NMTA Middle Level 24 Mathematics
Teacher Certification Exam
By: Sharon Wynne, M.S Southern Connecticut State University
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[email protected] Web www.xamonline.com Fax: 1-781-662-9268 Library of Congress Cataloging-in-Publication Data Wynne, Sharon A. Middle Level Mathematics 24: Teacher Certification / Sharon A. Wynne. -2nd ed. ISBN 978-1-60787-876-6 1. Middle Level Mathematics 24. 2. Study Guides. 3. NMTA 4. Teachers’ Certification & Licensure. 5. Careers
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NMTA: Middle Level Mathematics 24 ISBN: 978-1-60787-876-6
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TEACHER CERTIFICATION STUDY GUIDE
About the Subject Assessments NMTA™: Subject Assessment in the Middle Level Mathematics examination Purpose: The assessments are designed to test the knowledge and competencies of prospective secondary level teachers. The question bank from which the assessment is drawn is undergoing constant revision. As a result, your test may include questions that will not count towards your score. Test Version: There are two versions of subject assessment for Mathematics in New Mexico. The Middle Level Mathematics (24) exam emphasizes comprehension in Mathematical Reasoning, Problem Solving and Methods, Number Concepts and the Historical Development of Mathematics; Number Systems, Number Concepts, and Number Theory; Geometry and Measurement; Data Analysis, Statistics, and Probability; Patterns, Algebraic Relationships, and Functions. The Mathematics (024) exam emphasizes comprehension in Mathematical Processes, Number Concepts and their Historical Development; Geometry and Measurement; Data Analysis, Statistics, Probability, and Discrete Mathematics; Patterns, Algebraic Relationships, and Functions The Middle Level Mathematics study guide is based on a typical knowledge level of persons who have completed a bachelor’s degree program in Mathematics. Time Allowance, Format and Scoring: You will have 4 hours to finish the exam. There are approximately 100 multiple-choice questions in the exam. Additional Information about the NMTA Assessments: The NMTA series subject assessments are developed by National Evaluation Systems. They provide additional information on the NMTA series assessments, including registration, preparation and testing procedures and study materials such topical guides that have about 21 pages of information including approximately 10 additional sample questions.
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TEACHER CERTIFICATION STUDY GUIDE TABLE OF CONTENTS COMPETENCY # SUBAREA I.
PG #
MATHEMATICAL REASONING, PROBLEM SOLVING, AND METHODS, NUMBER CONCEPTS, AND THE HISTORICAL DEVELOPMENT OF MATHEMATICS ........................................ 1
Competency 0001
Understand and apply problem-solving strategies, connections among different mathematical ideas, and mathematical modeling to solve application problems encountered in life ................................................................ 1
Competency 0002
Understand principles of mathematical reasoning and techniques for communicating mathematical ideas .............. 4
Competency 0003
Understand the development of mathematical concepts, skills, and applications from their origins to current times, including the role of technology ............................................ 8
SUBAREA II.
NUMBER SYSTEMS, NUMBER CONCEPTS, AND NUMBER THEORY ...................................................................................... 10
Competency 0004
Understand number systems, number theory, and ways of representing numbers .......................................................... 10
Competency 0005
Understand operations on numbers and properties of number operations ............................................................... 18
SUBAREA III. GEOMETRY AND MEASUREMENT ........................................... 21 Competency 0006
Apply geometric concepts and reasoning, including twoand three-dimensional coordinate geometry ........................ 21
Competency 0007
Understand and use measurement ...................................... 35
SUBAREA IV. DATA ANALYSIS, STATISTICS, AND PROBABILITY .............. 50 Competency 0008
Understand methods of collecting, organizing, displaying, describing, and analyzing data ............................................. 50
Competency 0009
Understand the theory of probability and probability distributions .......................................................................... 61
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TEACHER CERTIFICATION STUDY GUIDE SUBAREA V.
PATTERNS, ALGEBRAIC RELATIONSHIPS, AND FUNCTIONS ................................................................................ 64
Competency 0010
Describe, analyze, and generalize mathematical patterns ... 64
Competency 0011
Use variables and symbolic expressions to describe and analyze patterns of change, functions, and relationships among variables ................................................................... 67
Competency 0012
Understand properties and applications of linear, quadratic, exponential, and trigonometric functions and solve related equations and inequalities.................................................... 84
Answer Key to Practice Problems ....................................................................... 111 Sample Test ........................................................................................................... 114 Answer Key ........................................................................................................... 143 Rationales for Sample Questions ........................................................................ 144
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TEACHER CERTIFICATION STUDY GUIDE
Great Study and Testing Tips! What to study in order to prepare for the subject assessments is the focus of this study guide; but equally important is how you study. You can increase your chances of truly mastering the information by taking some simple, but effective steps.
Study Tips: 1. Some foods aid the learning process. Foods such as milk, nuts, seeds, rice, and oats help your study efforts by releasing natural memory enhancers called CCKs (cholecystokinin) composed of tryptophan, choline, and phenylalanine. All of these chemicals enhance the neurotransmitters associated with memory. Before studying, try a light, protein-rich meal of eggs, turkey, and fish. All of these foods release the memory enhancing chemicals. The better the connections, the more you comprehend. Likewise, before you take a test, stick to a light snack of energy boosting and relaxing foods. A glass of milk, a piece of fruit, or some peanuts all release various memory-boosting chemicals and help you to relax and focus on the subject at hand. 2. Learn to take great notes. A by-product of our modern culture is that we have grown accustomed to getting our information in short doses (i.e. TV news sound bites or USA Today style newspaper articles.) Consequently, we’ve subconsciously trained ourselves to assimilate information better in neat little packages. If your notes are scrawled all over the paper, it fragments the flow of the information. Strive for clarity. Newspapers use a standard format to achieve clarity. Your notes can be much clearer through use of proper formatting. A very effective format is called the “Cornell Method.” Take a sheet of loose-leaf lined notebook paper and draw a line all the way down the paper about 1-2” from the left-hand edge. Draw another line across the width of the paper about 1-2” up from the bottom. Repeat this process on the reverse side of the page. Look at the highly effective result. You have ample room for notes, a left hand margin for special emphasis items or inserting supplementary data from the textbook, a large area at the bottom for a brief summary, and a little rectangular space for just about anything you want.
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TEACHER CERTIFICATION STUDY GUIDE 3. Get the concept, then the details. Too often we focus on the details and don’t gather an understanding of the concept. However, if you simply memorize only dates, places, or names, you may well miss the whole point of the subject. A key way to understand things is to put them in your own words. If you are working from a textbook, automatically summarize each paragraph in your mind. If you are outlining text, don’t simply copy the author’s words. Rephrase them in your own words. You remember your own thoughts and words much better than someone else’s, and subconsciously tend to associate the important details to the core concepts. 4. Ask Why? Pull apart written material, paragraph by paragraph; and don’t forget the captions under the illustrations. Example: If the heading is “Stream Erosion”, flip it around to read “Why do streams erode?” Then answer the questions. If you train your mind to think in a series of questions and answers, not only will you learn more, but you’ll also find that your test anxiety is lessened, because you’re used to answering questions. 5. Read for reinforcement and future needs. Even if you only have 10 minutes, put your notes or a book in your hand. Your mind is similar to a computer; you have to input data in order to have it processed. By reading, you are creating the neural connections for future retrieval. The more times you read something, the more you reinforce the learning of ideas. Even if you don’t fully understand something on the first pass, your mind stores much of the material for later recall. 6. Relax to learn; go into exile. Our bodies respond to an inner clock called biorhythms. Burning the midnight oil works well for some people, but not everyone. If possible, set aside a particular place to study that is free of distractions. Shut off the television, cell phone, pager and exile your friends and family during your study period. If you really are bothered by silence, try background music. Light classical music at a low volume has been shown to aid in concentration over other types. Music that evokes pleasant emotions without lyrics are highly suggested. Try just about anything by Mozart. It relaxes you.
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TEACHER CERTIFICATION STUDY GUIDE 7. Use arrows, not highlighters. At best, it’s difficult to read a page full of yellow, pink, blue, and green streaks. Try staring at a neon sign for a while and you’ll soon see that the horde of colors obscures the message. A quick note, a brief dash of color, an underline, and an arrow pointing to a particular passage is much clearer than a rainbow of highlighted words. 8. Budget your study time. Although you shouldn’t ignore any of the material, allocate your available study time in the same ratio that topics may appear on the test.
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TEACHER CERTIFICATION STUDY GUIDE
Testing Tips: 1. Get smart, play dumb. Don’t read anything into the question. Don’t make an assumption that the test writer is looking for something other than what is asked. Stick to the question as written, and don’t read extra things into it. 2. Read the question and all the choices twice before answering the question. You may miss something by not carefully reading, and then rereading both the question and the answers. If you really don’t have a clue as to the right answer, leave it blank on the first time through. Go on to the other questions, as they may provide a clue as to how to answer the skipped questions. If, later on, you still can’t answer the skipped ones . . . Guess. The only penalty for guessing is that you might get it wrong. Only one thing is certain; if you don’t put anything down, you will get it wrong! 3. Turn the question into a statement. Look at the way the questions are worded. The syntax of the question usually provides a clue. Does it seem more familiar as a statement rather than as a question? Does it sound strange? By turning a question into a statement, you may be able to spot if an answer sounds right, and it may also trigger memories of material you have read. 4. Look for hidden clues. It’s actually very difficult to compose multiple-foil (choice) questions without giving away part of the answer in the options presented. In most multiple-choice questions you can often readily eliminate one or two of the potential answers. This leaves you with only two real possibilities and automatically your odds go to Fifty-Fifty for very little work. 5. Trust your instincts. For every fact that you have read, you subconsciously retain something of that knowledge. On questions that you aren’t really certain about, go with your basic instincts. Your first impression on how to answer a question is usually correct. 6. Mark your answers directly on the test booklet. Don’t bother trying to fill in the optical scan sheet on the first pass through the test. Just be very careful not to mis-mark your answers when you eventually transcribe them to the scan sheet. 7. Watch the clock! You have a set amount of time to answer the questions. Don’t get bogged down trying to answer a single question at the expense of 10 questions you can more readily answer.
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TEACHER CERTIFICATION STUDY GUIDE SUBAREA I. MATHEMATICAL REASONING, PROBLEM SOLVING AND METHODS, NUMBER CONCEPTS, AND THE HISTORICAL DEVELOPMENT OF MATHEMATICS Competency 0001
Understand and apply problem-solving strategies, connections among different mathematical ideas, and mathematical modeling to solve application problems encountered in life.
Successful math teachers introduce their students to multiple problem solving strategies and create a classroom environment where free thought and experimentation are encouraged. Teachers can promote problem solving by allowing multiple attempts at problems, giving credit for reworking test or homework problems, and encouraging the sharing of ideas through class discussion. There are several specific problem solving skills with which teachers should be familiar. The guess-and-check strategy calls for students to make an initial guess at the solution, check the answer, and use the outcome of to guide the next guess. With each successive guess, the student should get closer to the correct answer. Constructing a table from the guesses can help organize the data. Example: There are 100 coins in a jar. 10 are dimes. The rest are pennies and nickels. There are twice as many pennies as nickels. How many pennies and nickels are in the jar? There are 90 total nickels and pennies in the jar (100 coins – 10 dimes). There are twice as many pennies as nickels. Make guesses that fulfill the criteria and adjust based on the answer found. Continue until we find the correct answer, 60 pennies and 30 nickels. Number of Pennies Number of Nickels 40 80 70 60
MIDDLE LEVEL MATH.
20 40 35 30
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Total Number of Pennies and Nickels 60 120 105 90
TEACHER CERTIFICATION STUDY GUIDE When solving a problem where the final result and the steps to reach the result are given, students must work backwards to determine what the starting point must have been. Example: John subtracted seven from his age, and divided the result by 3. The final result was 4. What is John’s age? Work backward by reversing the operations. 4 x 3 = 12; 12 + 7 = 19 John is 19 years old. Estimation and testing for reasonableness are related skills students should employ both before and after solving a problem. These skills are particularly important when students use calculators to find answers. Example: Find the sum of 4387 + 7226 + 5893. 4300 + 7200 + 5800 = 17300 4387 + 7226 + 5893 = 17506
Estimation. Actual sum.
By comparing the estimate to the actual sum, students can determine that their answer is reasonable. Recognition and understanding of the relationships between concepts and topics is of great value in mathematical problem solving and the explanation of more complex processes. For instance, multiplication is simply repeated addition. This relationship explains the concept of variable addition. We can show that the expression 4x + 3x = 7x is true by rewriting 4 times x and 3 times x as repeated addition, yielding the expression (x + x + x + x) + (x + x + x). Thus, because of the relationship between multiplication and addition, variable addition is accomplished by coefficient addition.
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TEACHER CERTIFICATION STUDY GUIDE Another example of a mathematical relationship is exponents as repeated multiplication. This relationship explains the rules of exponent operations. For instance, the multiplication of exponential terms with like bases is accomplished by the addition of the exponents. 22 x 2 5 = 2 7 (2 x 2) + (2 x 2 x 2 x 2 x 2) = 22 + 5 = 27 This rule yields the general formula for the product of exponential terms, zm x zn = zm+n, that is useful in problem solving. Because mathematics problems and concepts are often presented in written form, students must have the ability to interpret written presentations and reproduce the concepts in symbolic form to facilitate manipulation and problem solving. Correct interpretation requires a sound understanding of the vocabulary of mathematics. There are many types of written presentations of mathematics, and the following are but two examples. Examples: 1. The square of the hypotenuse of a right triangle is equivalent to the sum of the squares of the two legs. a 2 + b 2 = c2 2. Find the velocity of an object at time t given the object’s position function is f(t) = t2 – 8t + 9. The velocity at a given time (t) is equal to the value of the derivative of the position function at t. Thus… v(t) = f’(t) = 2t – 8 The velocity after t seconds is 2t – 8.
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TEACHER CERTIFICATION STUDY GUIDE Competency 0002
Understand principles of mathematical reasoning and techniques for communicating mathematical ideas.
Examples, illustrations, and symbolic representations are useful tools in explaining and understanding mathematical concepts. The ability to create examples and alternative methods of expression allows students to solve real world problems and better communicate their thoughts. Concrete examples are real world applications of mathematical concepts. For example, measuring the shadow produced by a tree or building is a real world application of trigonometric functions; acceleration or velocity of a car is an application of derivatives; and finding the volume or area of a swimming pool is a real world application of geometric principles. Pictorial illustrations of mathematic concepts help clarify difficult ideas and simplify problem solving. Examples: 1. Rectangle R represents the 300 students in School A. Circle P represents the 150 students that participated in band. Circle Q represents the 170 students that participated in a sport. 70 students participated in both band and a sport.
Pictorial representation of above situation. 2. A ball rolls up an incline and rolls back to its original position. Create a graph of the velocity of the ball.
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Velocity starts out at its maximum as the ball begins to roll, decreases to zero at the top of the incline, and returns to the maximum in the opposite direction at the bottom of the incline.
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TEACHER CERTIFICATION STUDY GUIDE Symbolic representation is the basic language of mathematics. Converting data to symbols allows for easy manipulation and problem solving. Students should have the ability to recognize what the symbolic notation represents and convert information into symbolic form. For example, from the graph of a line, students should have the ability to determine the slope and intercepts and derive the line’s equation from the observed data. Another possible application of symbolic representation is the formulation of algebraic expressions and relations from data presented in word problem form. Conditional statements can be diagrammed using a Venn diagram. A diagram can be drawn with one figure inside another figure. The inner figure represents the hypothesis. The outer figure represents the conclusion. If the hypothesis is taken to be true, then you are located inside the inner figure. If you are located in the inner figure then you are also inside the outer figure, so that proves the conclusion is true. Sometimes that conclusion can then be used as the hypothesis for another conditional, which can result in a second conclusion. Suppose that these statements were given to you, and you are asked to try to reach a conclusion. The statements are: All swimmers are athletes. All athletes are scholars. In "if-then" form, these would be: If you are a swimmer, then you are an athlete. If you are an athlete, then you are a scholar.
Scholars
Clearly, if you are a swimmer, then you are also an athlete. This includes you in the group of scholars.
ATHLETES swimmers
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TEACHER CERTIFICATION STUDY GUIDE Suppose that these statements were given to you, and you are asked to try to reach a conclusion. The statements are: All swimmers are athletes. All wrestlers are athletes. In "if-then" form, these would be: If you are a swimmer, then you are an athlete. If you are a wrestler, then you are an athlete. ATHLETE
wrestler
swimmer
Clearly, if you are a swimmer or a wrestler, then you are also an athlete. This does NOT allow you to come to any other conclusions.
A swimmer may or may NOT also be a wrestler. Therefore, NO CONCLUSION IS POSSIBLE. Suppose that these statements were given to you, and you are asked to try to reach a conclusion. The statements are: All rectangles are parallelograms. Quadrilateral ABCD is not a parallelogram. In "if-then" form, the first statement would be: If a figure is a rectangle, then it is also a parallelogram. Note that the second statement is the negation of the conclusion of statement one. Remember also that the contrapositive is logically equivalent to a given conditional. That is, "If q, then p". Since" ABCD is NOT a parallelogram " is like saying "If q," then you can come to the conclusion "then p". Therefore, the conclusion is ABCD is not a rectangle. Looking at the Venn diagram below, if all rectangles are parallelograms, then rectangles are included as part of parallelograms. Since quadrilateral ABCD is not a parallelogram, it is excluded from anywhere inside the parallelogram box. This allows you to conclude that ABCD can not be a rectangle either.
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TEACHER CERTIFICATION STUDY GUIDE
PARALLELOGRAMS
quadrilateral ABCD
rectangles
Try These: What conclusion, if any, can be reached? Assume each statement is true, regardless of any personal beliefs. 1. If the Red Sox win the World Series, I will die. I died. 2. If an angle's measure is between 0° and 90°, then the angle is acute. Angle B is not acute. 3. Students who do well in geometry will succeed in college. Annie is doing extremely well in geometry. 4. Left-handed people are witty and charming. You are left-handed. Inductive thinking is the process of finding a pattern from a group of examples. That pattern is the conclusion that this set of examples seems to indicate. It may be a correct conclusion or it may be an incorrect conclusion, because other examples may not follow the predicted pattern. Deductive thinking is the process of arriving at a conclusion based on other statements that are all known to be true, such as theorems, axioms, or postulates. Conclusions found by deductive thinking based on true statements will always be true. Examples: Suppose: On Monday Mr. Peterson eats breakfast at McDonalds. On Tuesday Mr. Peterson eats breakfast at McDonalds. On Wednesday Mr. Peterson eats breakfast at McDonalds. On Thursday Mr. Peterson eats breakfast at McDonalds again. Conclusion: On Friday Mr. Peterson will eat breakfast at McDonalds again. This is a conclusion based on inductive reasoning. Based on several days observations, you conclude that Mr. Peterson will eat at McDonalds. This may or may not be true, but it is a conclusion arrived at by inductive thinking.
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TEACHER CERTIFICATION STUDY GUIDE Competency 0003
Understand the development of mathematical concepts, skills, and applications from their origins to current times, including the role of technology.
Mathematics dates back before recorded history. Prehistoric cave paintings with geometrical figures and slash counting have been dated prior to 20,000 BC in Africa and France. The major early uses of mathematics were for astronomy, architecture, trading and taxation. The early history of mathematics is found in Mesopotamia (Sumeria and Babylon), Egypt, Greece and Rome. Noted mathematicians from these times include Euclid, Pythagoras, Apollonius, Ptolemy and Archimedes. Islamic culture from the 6th through 12th centuries drew from areas ranging from Africa and Spain to India. Through India, they also drew on China. This mix of cultures and ideas brought about developments in many areas, including the concept of algebra, our current numbering system, and major developments in algebra with concepts such as zero. India was the source of many of these developments. Notable scholars of this era include Omar Khayyam and Muhammad al-Khwarizmi. Counting boards have been found in archeological digs in Babylonia and Greece. These include the Chinese abacus whose current form dates from approximately 1200 AD. Prior to the development of the zero, a counting board or abacus was the common method used for all types of calculations. Abelard and Fibonacci brought Islamic texts to Europe in the 12th century. By the 17th century, major new works appeared from Galileo and Copernicus (astronomy), Newton and Leibniz (calculus), and Napier and Briggs (logarithms). Other significant mathematicians of this era include René Descartes, Carl Gauss, Pierre de Fermat, Leonhard Euler and Blaise Pascal.
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TEACHER CERTIFICATION STUDY GUIDE The growth of mathematics since 1800 has been enormous, and has affected nearly every area of life. Some names significant in the history of mathematics since 1800 (and the work they are most known for): Joseph-Louis Lagrange (theory of functions and of mechanics) Pierre-Simon Laplace (celestial mechanics, probability theory) Joseph Fourier (number theory) Lobachevsky and Bolyai (non-Euclidean geometry) Charles Babbage (calculating machines, origin of the computer) Lady Ada Lovelace (first known program) Florence Nightingale (nursing, statistics of populations) Bertrand Russell (logic) James Maxwell (differential calculus and analysis) John von Neumann (economics, quantum mechanics and game theory) Alan Turing (theoretical foundations of computer science) Albert Einstein (theory of relativity) Gustav Roch (topology) Calculators are an important tool. Their use should be encouraged in the classroom and at home. They do not replace basic knowledge, but they can relieve the tedium of mathematical computations, allowing students to explore more challenging mathematical directions. Students will be able to use calculators more intelligently if they are taught how. Students need to always check their work by estimating. The goal of mathematics is to prepare the child to survive in the real world. Technology is a reality in today’s society. Computers can not replace teachers. However, they can be used to enhance the curriculum. They may be used cautiously to help students practice basic skills. Many excellent programs exist to encourage higher-order thinking skills, creativity and problem solving. Learning to use technology appropriately is an important preparation for adulthood. Computers can also show the connections between mathematics and the real world.
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TEACHER CERTIFICATION STUDY GUIDE SUBAREA II. NUMBER SYSTEMS, NUMBER CONCEPTS, AND NUMBER THEORY Competency 0004
Understand number systems, number theory, and ways of representing numbers.
A numeration system is a set of numbers represented a by a set of symbols (numbers, letters, or pictographs). Sets can have different bases of numerals within the set. Instead of our base 10, a system may use any base set from 2 on up. The position of the number in that representation defines its exact value. Thus, the numeral 1 has a value of ten when represented as “10”. Early systems, such as the Babylonian, used position in relation to other numerals or column position for this purpose since they lacked a zero to represent an empty position. A base of 2 uses only 0 and 1. Decimal Binary Conversion Decimal Binary Place Value 1 1 20 2 10 21 4 100 22 8 1000 23 Thus, 9 in Base 10 becomes 1001 in Base 2. 9+4 = 13 (Base 10) becomes 1001 + 100 = 1101 (Base 2). Fractions, ratios and other functions alter in the same way. Computers use a base of 2 but combine it into 4 units called a byte to function in base 16 (hexadecimal). A base of 8 (octal) was also used by older computers. Prime numbers are numbers that can only be factored into 1 and the number itself. When factoring into prime factors, all the factors must be numbers that cannot be factored again (without using 1). Initially numbers can be factored into any 2 factors. Check each resulting factor to see if it can be factored again. Continue factoring until all remaining factors are prime. This is the list of prime factors. Regardless of which way the original number was factored, the final list of prime factors will always be the same.
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TEACHER CERTIFICATION STUDY GUIDE Example: Factor 30 into prime factors. Divide by 2 as many times as you can, then by 3, then by other successive primes as required. 2·2·2·2·2·2·2·2·2·2·2·2·2·2·2 Factor 30 into any 2 factors. 5·6 5·2·3
Now factor the 6. These are all prime factors.
Factor 30 into any 2 factors. 3 · 10 3·2·5
Now factor the 10. These are the same prime factors even though the original factors were different.
Example: Factor 240 into prime factors. Factor 240 into any 2 factors. 24 · 10 4·6·2·5 2·2·2·3·2·5
Now factor both 24 and 10. Now factor both 4 and 6. These are prime factors.
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This can also be written as 2 · 3 · 5 GCF is the abbreviation for the greatest common factor. The GCF is the largest number that is a factor of all the numbers given in a problem. The GCF can be no larger than the smallest number given in the problem. If no other number is a common factor, then the GCF will be the number 1. To find the GCF, list all possible factors of the smallest number given (include the number itself). Starting with the largest factor (which is the number itself), determine if it is also a factor of all the other given numbers. If so, that is the GCF. If that factor does not work, try the same method on the next smaller factor. Continue until a common factor is found. That is the GCF. Note: There can be other common factors besides the GCF. Example: Find the GCF of 12, 20, and 36. The smallest number in the problem is 12. The factors of 12 are 1, 2, 3, 4, 6, and 12. The largest factor is 12, but it does not divide evenly into 20. Neither does 6, but 4 will divide into both 20 and 36 evenly. Therefore, 4 is the GCF. MIDDLE LEVEL MATH.
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TEACHER CERTIFICATION STUDY GUIDE Example: Find the GCF of 14 and 15. Factors of 14 are 1, 2, 7, and 14. The largest factor is 14, but it does not divide evenly into 15. Neither does 7 or 2. Therefore, the only factor common to both 14 and 15 is the number 1, the GCF. LCM is the abbreviation for least common multiple. The least common multiple of a group of numbers is the smallest number into which all of the given numbers will divide. The least common multiple will always be the largest of the given numbers or a multiple of the largest number. Example: Find the LCM of 20, 30, and 40. The largest number given is 40, but 30 will not divide evenly into 40. The next multiple of 40 is 80 (2 x 40), but 30 will not divide evenly into 80 either. The next multiple of 40 is 120. 120 is divisible by both 20 and 30, so 120 is the LCM (least common multiple). Example: Find the LCM of 96, 16, and 24. The largest number is 96. The number 96 is divisible by both 16 and 24, so 96 is the LCM. a. A number is divisible by 2 if that number is an even number (which means it ends in 0,2,4,6 or 8). 1,354 ends in 4, so it is divisible by 2. 240,685 ends in a 5, so it is not divisible by 2. b. A number is divisible by 3 if the sum of its digits is evenly divisible by 3. The sum of the digits of 964 is 9+6+4 = 19. Since 19 is not divisible by 3, neither is 964. The digits of 86,514 are 8+6+5+1+4 = 24. Since 24 is divisible by 3, 86,514 is also divisible by 3. c. A number is divisible by 4 if the number in its last 2 digits is evenly divisible by 4. The number 113,336 ends with the number 36 in the last 2 columns. Since 36 is divisible by 4, then 113,336 is also divisible by 4.
MIDDLE LEVEL MATH.
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TEACHER CERTIFICATION STUDY GUIDE The number 135,627 ends with the number 27 in the last 2 columns. Since 27 is not evenly divisible by 4, then 135,627 is also not divisible by 4. d. A number is divisible by 5 if the number ends in either a 5 or a 0. 225 ends with a 5 so it is divisible by 5. The number 470 is also divisible by 5 because its last digit is a 0. 2,358 is not divisible by 5 because its last digit is an 8, not a 5 or a 0. e. A number is divisible by 6 if the number is even and the sum of its digits is evenly divisible by 3. 4,950 is an even number and its digits add to 18. (4+9+5+0 = 18) Since the number is even and the sum of its digits is 18 (which is divisible by 3), then 4950 is divisible by 6. 326 is an even number, but its digits add up to 11. Since 11 is not divisible by 3, then 326 is not divisible by 6. 698,135 is not an even number, so it cannot possibly be divided evenly by 6. f. A number is divisible by 8 if the number in its last 3 digits is evenly divisible by 8. The number 113,336 ends with the 3-digit number 336 in the last 3 places. Since 336 is divisible by 8, then 113,336 is also divisible by 8. The number 465,627 ends with the number 627 in the last 3 places. Since 627 is not evenly divisible by 8, then 465,627 is also not divisible by 8. g. A number is divisible by 9 if the sum of its digits is evenly divisible by 9. The sum of the digits of 874 is 8+7+4 = 19. Since 19 is not divisible by 9, neither is 874. The digits of 116,514 is 1+1+6+5+1+4 = 18. Since 18 is divisible by 9, 116,514 is also divisible by 9. h. A number is divisible by 10 if the number ends in the digit 0. 305 ends with a 5 so it is not divisible by 10. The number 2,030,270 is divisible by 10 because its last digit is a 0. 42,978 is not divisible by 10 because its last digit is an 8, not a 0.
MIDDLE LEVEL MATH.
13
TEACHER CERTIFICATION STUDY GUIDE i. Why these rules work. All even numbers are divisible by 2 by definition. A 2-digit number (with T as the tens digit and U as the units digit) has as its sum of the digits, T + U. Suppose this sum of T + U is divisible by 3. Then it equals 3 times some constant, K. So, T + U = 3K. Solving this for U, U = 3K - T. The original 2 digit number would be represented by 10T + U. Substituting 3K - T in place of U, this 2-digit number becomes 10T + U = 10T + (3K - T) = 9T + 3K. This 2-digit number is clearly divisible by 3, since each term is divisible by 3. Therefore, if the sum of the digits of a number is divisible by 3, then the number itself is also divisible by 3. Since 4 divides evenly into 100, 200, or 300, 4 will divide evenly into any amount of hundreds. The only part of a number that determines if 4 will divide into it evenly is the last 2 places. Numbers divisible by 5 end in 5 or 0. This is clear if you look at the answers to the multiplication table for 5. Answers to the multiplication table for 6 are all even numbers. Since 6 factors into 2 times 3, the divisibility rules for 2 and 3 must both work. Any number of thousands is divisible by 8. Only the last 3 places of the number determine whether or not it is divisible by 8. A 2 digit number (with T as the tens digit and U as the units digit) has, as its sum of the digits, T + U. Suppose this sum of T + U is divisible by 9. Then it equals 9 times some constant, K. So, T + U = 9K. Solving this for U, U = 9K - T. The original 2-digit number would be represented by 10T + U. Substituting 9K - T in place of U, this 2digit number becomes 10T + U = 10T + (9K - T) = 9T + 9K. This 2digit number is clearly divisible by 9, since each term is divisible by 9. Therefore, if the sum of the digits of a number is divisible by 9, then the number itself is also divisible by 9. Numbers divisible by 10 must be multiples of 10 which all end in a zero. Fractions, decimals, and percents can be used interchangeably within problems.
→ To change a percent into a decimal, move the decimal point two places to the left and drop the percent sign. → To change a decimal into a percent, move the decimal two places to the right and add a percent sign.
→ To change a fraction into a decimal, divide the numerator by the denominator.
MIDDLE LEVEL MATH.
14
TEACHER CERTIFICATION STUDY GUIDE
→ To change a decimal number into an equivalent fraction, write the decimal part of the number as the fraction's numerator. As the fraction's denominator use the place value of the last column of the decimal. Reduce the resulting fraction as far as possible. Example: J.C. Nickels has Hunch jeans 1 4 off the usual price of $36.00. Shears and Roadkill have the same jeans 30% off their regular price of $40. Find the cheaper price.
1 4 = .25 so .25(36) = $9.00 off. $36 - 9 = $27 sale price 30% = .30 so .30(40) = $12 off. $40 - 12 = $28 sale price The price at J.C Nickels is actually lower. To change a number into scientific notation, move the decimal point so that only a single digit is to the left of the decimal point. Drop off any trailing zeros. Multiply this number times 10 to a power. The power is the number of positions that the decimal point is moved. The power is negative if the original number is a decimal number between 1 and -1. Otherwise the power is positive. Example: Change into scientific notation: Move decimal behind the 4 Drop trailing zeros. Count positions that the decimal point has moved. This is the answer.
4, 380, 000, 000 4.38 4.38 × 10?
4.38 × 109 −
Move decimal behind the 4 Count positions that the decimal point has moved. Note negative exponent.
.0000407 − 4.07
4.07 × 10−5
If a number is already in scientific notation, it can be changed back into regular decimal form. If the exponent on the number 10 is negative, move the decimal point to the left that number of places.. If the exponent on the number 10 is positive, move the decimal point to the right.
MIDDLE LEVEL MATH.
15
TEACHER CERTIFICATION STUDY GUIDE Example: Change back into decimal form: 3.448 x 10-2 .03448
6 × 10 4 60,000
Move decimal point 2 places left, since exponent is negative. This is the answer. Move decimal point 4 places right, since exponent is positive. This is the answer.
To add or subtract in scientific notation, the exponents must be the same. Then add the decimal portions, keeping the power of 10 the same. Then move the decimal point and adjust the exponent to keep the number to the left of the decimal point to a single digit. Example: 6.22 × 103 + 7.48 × 103 13.70 × 103 1.37 × 10 4
Add these as is. Now move decimal 1 more place to the left and add 1 more exponent.
To multiply or divide in scientific notation, multiply or divide the decimal part of the numbers. In multiplication, add the exponents of 10. In division, subtract the exponents of 10. Then move the decimal point and adjust the exponent to keep the number to the left of the decimal point to a single digit. Example: (5.2 × 105 )(3.5 × 102 ) 18.2 × 10
7
1.82 × 108
Multiply 5.2 ⋅ 3.5 Add exponent Move decimal point and increase the exponent by 1.
Example: (4.1076 × 103 ) 2.8 × 10 −4
Divide 4.1076 by 2.8 Subtract 3 − ( − 4)
1.467 × 107
MIDDLE LEVEL MATH.
16
TEACHER CERTIFICATION STUDY GUIDE Students of mathematics must be able to recognize and interpret the different representations of arithmetic operations. First, there are many different verbal descriptions for the operations of addition, subtraction, multiplication, and division. The table below identifies several words and/or phrases that are often used to denote the different arithmetic operations. Operation Addition Subtraction Multiplication Division
Descriptive Words “plus”, “combine”, “sum”, “total”, “put together” “minus”, “less”, “take away”, “difference” “product”, “times”, “groups of” “quotient”, “into”, “split into equal groups”,
Second, diagrams of arithmetic operations can present mathematical data in visual form. For example, we can use the number line to add and subtract. -6 -5 -4 -3 -2 -1 0
1
2 3 4
5 6
The addition of 5 to -4 on the number line; -4 + 5 = 1. Finally, as shown in the examples below, we can use pictorial representations to explain all of the arithmetic processes.
Two groups of four will equal eight or 2 x 4 = 8 shown in picture form.
=
Adding three objects to two or 3 + 2 = 5 shown in picture form.
MIDDLE LEVEL MATH.
17
TEACHER CERTIFICATION STUDY GUIDE Competency 0005
Understand operations on numbers and properties of number operations.
The real number properties are best explained in terms of a small set of numbers. For each property, a given set will be provided. Axioms of Addition Closure—For all real numbers a and b, a + b is a unique real number. Associative—For all real numbers a, b, and c, (a + b) + c = a + (b + c). Additive Identity—There exists a unique real number 0 (zero) such that a + 0 = 0 + a = a for every real number a. Additive Inverses—For each real number a, there exists a real number –a (the opposite of a) such that a + (-a) = (-a) + a = 0. Commutative—For all real numbers a and b, a + b = b +a. Axioms of Multiplication Closure—For all real numbers a and b, ab is a unique real number. Associative—For all real numbers a, b, and c, (ab)c = a(bc). Multiplicative Identity—There exists a unique nonzero real number 1 (one) such that = 1  a a= , a 1 a. Multiplicative Inverses—For each nonzero real number, there exists a real number 1/a (the reciprocal of a) such that a(1/a) = (1/a)a = 1. Commutative—For all real numbers a and b, ab = ba. The Distributive Axiom of Multiplication over Addition For all real numbers a, b, and c, a(b + c) = ab + ac.
MIDDLE LEVEL MATH.
18
TEACHER CERTIFICATION STUDY GUIDE A ratio is a comparison of 2 numbers. If a class had 11 boys and 14 girls, the ratio of boys to girls could be written one of 3 ways: 11:14
or
11 to 14 or
11 14
The ratio of girls to boys is: 14:11, 14 to 11 or
14 11
Ratios can be reduced when possible. A ratio of 12 cats to 18 dogs would reduce to 2:3, 2 to 3 or 2 3 . Note: Read ratio questions carefully. Given a group of 6 adults and 5 children, the ratio of children to the entire group would be 5:11. A proportion is an equation in which a fraction is set equal to another. To solve the proportion, multiply each numerator times the other fraction's denominator. Set these two products equal to each other and solve the resulting equation. This is called crossmultiplying the proportion. Example:
4 x is a proportion. = 15 60
To solve this, cross multiply.
(4)(60) = (15)( x ) 240 = 15 x 16 = x Example:
x +3 2 = is a proportion. 3x + 4 5
To solve, cross multiply.
5( x + 3)= 2(3 x + 4) 5 x + 15 = 6 x + 8 7=x
MIDDLE LEVEL MATH.
19
TEACHER CERTIFICATION STUDY GUIDE x+2 2 = 8 x−4
Example:
is another proportion.
To solve, cross multiply. 8(2) ( x + 2 )( x − 4 ) = x 2 − 2x − 8 = 16 x 2 − 2 x − 24 = 0 ( x − 6)( x + 4) = 0 = x 6= or x
−
4
Both answers work. Subtraction is the inverse of Addition, and vice-versa. Division is the inverse of Multiplication, and vice-versa. Taking a square root is the inverse of squaring, and vice-versa. These inverse operations are used when solving equations.
MIDDLE LEVEL MATH.
20
TEACHER CERTIFICATION STUDY GUIDE SUBAREA III. GEOMETRY AND MEASUREMENT Competency 0006
Apply geometric concepts and reasoning, including two- and three-dimensional coordinate geometry.
Congruent figures have the same size and shape. If one is placed above the other, it will fit exactly. Congruent lines have the same length. Congruent angles have equal measures. The symbol for congruent is ≅ . Polygons (pentagons) ABCDE and VWXYZ are congruent. They are exactly the same size and shape. A B V W
C
X
E
Z D
Y
ABCDE ≅ VWXYZ Corresponding parts are those congruent angles and congruent sides, that is: corresponding angles corresponding sides ∠A ↔ ∠V AB ↔ VW ∠B ↔ ∠W BC ↔ WX ∠C ↔ ∠X CD ↔ XY ∠D ↔ ∠ Y DE ↔ YZ ∠E ↔ ∠Z AE ↔ VZ Two figures that have the same shape are similar. Two polygons are similar if corresponding angles are congruent and corresponding sides are in proportion. Corresponding parts of similar polygons are proportional. 25 15 20
35
30
MIDDLE LEVEL MATH.
12
21
18
21
TEACHER CERTIFICATION STUDY GUIDE SIMILAR TRIANGLES AA Similarity Postulate If two angles of one triangle are congruent to two angles of another triangle, then the triangles are similar. SAS Similarity Theorem If an angle of one triangle is congruent to an angle of another triangle and the sides adjacent to those angles are in proportion, then the triangles are similar. SSS Similarity Theorem If the sides of two triangles are in proportion, then the triangles are similar. Example: 8
18
6 24 The two triangles are similar since the sides are proportional and the vertical angles are congruent. Example: Given two similar quadrilaterals. Find the lengths of sides x, y, and z. 25 15 x
y
12
30
21
z
Since corresponding sides are proportional: 15 3 3 = so the scale is 25 5 5 12 3 = x 5
3x = 60 x = 20
MIDDLE LEVEL MATH.
21 3 = 5 y 3y = 105 y = 35
22
z 3 = 30 5
5z = 90 z = 18
TEACHER CERTIFICATION STUDY GUIDE Exercise: a)
One line passes through the points (-4, -6) and (4, 6); another line passes through the points (-5, -4) and (3, 8). Are these lines parallel, perpendicular or neither? Find the slopes. m=
y2 − y1 x2 − x1
m= 1
6 − (−6) 6 + 6 12 3 = = = 4 − (−4) 4 + 4 8 2
m= 2
8 − (−4) 8 + 4 12 3 = = = 3 − (−5) 3 + 5 8 2
Since the slopes are the same, the lines are parallel. b)
One line passes through the points (1, -3) and (0, -6); another line passes through the points (4, 1) and (-2, 3). Are these lines parallel, perpendicular or neither? Find the slopes. m=
y2 − y1 x2 − x1
m = 1
−6 − (−3) −6 + 3 −3 = = = 3 0 −1 −1 −1
m2 =
3 −1 2 1 = = − −2 − 4 −6 3
The slopes are negative reciprocals, so the lines are perpendicular.
MIDDLE LEVEL MATH.
23
TEACHER CERTIFICATION STUDY GUIDE c)
One line passes through the points (-2, 4) and (2, 5); another line passes through the points (-1, 0) and (5, 4). Are these lines parallel, perpendicular or neither? Find the slopes. m=
y2 − y1 x2 − x1
5−4 1 1 = = 2 − (−2) 2 + 2 4
= m 1
m2=
4−0 4 4 2 = = = 5 − (−1) 5 + 1 6 3
Since the slopes are not the same, the lines are not parallel. Since they are not negative reciprocals, they are not perpendicular, either. Therefore, the answer is “neither.” Two triangles can be proven congruent by comparing pairs of appropriate congruent corresponding parts. SSS POSTULATE If three sides of one triangle are congruent to three sides of another triangle, then the two triangles are congruent. A
X
B
C
Z
Since AB ≅ XY, BC ≅ YZ and AC ≅ XZ, then ∆ABC ≅ ∆ XYZ.
MIDDLE LEVEL MATH.
24
Y
TEACHER CERTIFICATION STUDY GUIDE Example: Given isosceles triangle ABC with D the midpoint of base AC, prove the two triangles formed by AD are congruent. B
A
D
C
Proof: 1. Isosceles triangle ABC, D midpoint of base AC 2. AB ≅ BC
Given An isosceles ∆ has two congruent sides Midpoint divides a line into two equal parts Reflexive SSS
3. AD ≅ DC 4. BD ≅ BD 5. ∆ ABD ≅ ∆BCD SAS POSTULATE
If two sides and the included angle of one triangle are congruent to two sides and the included angle of another triangle, then the two triangles are congruent. P
S
R
Q
U
T
Example:
9
9
80o
80o 14
14
The two triangles are congruent by SAS.
MIDDLE LEVEL MATH.
25
TEACHER CERTIFICATION STUDY GUIDE ASA POSTULATE If two angles and the included side of one triangle are congruent to two angles and the included side of another triangle, the triangles are congruent. A
Z B
Y
C X ∠A ≅ ∠X, ∠B ≅ ∠Y, AB≅XY then ∆ABC ≅ ∆XYZ by ASA Example 1: Given two right triangles with one leg of each measuring 6 cm and the adjacent angle 37o, prove the triangles are congruent. A K
B
C
L
1. Right triangles ABC and KLM AB = KL = 6 cm ∠A = ∠K = 37o 2. AB ≅ KL ∠A ≅∠K 3. ∠B ≅ ∠L 4. ∆ABC ≅ ∆ KLM
M Given
Figures with the same measure are congruent All right angles are congruent. ASA
Example 2: What method would you use to prove the triangles congruent?
ASA because vertical angles are congruent.
MIDDLE LEVEL MATH.
26
TEACHER CERTIFICATION STUDY GUIDE AAS THEOREM If two angles and a non-included side of one triangle are congruent to the corresponding parts of another triangle, then the triangles are congruent. X A
Z B
C
Y
∠B ≅∠Y, ∠C ≅ ∠Z, AC≅XZ, then ∆ABC ≅ ∆XYZ by AAS. We can derive this theorem because if two angles of the triangles are congruent, then the third angle must also be congruent. Therefore, we can use the ASA postulate. HL THEOREM If the hypotenuse and a leg of one right triangle are congruent to the corresponding parts of another right triangle, the triangles are congruent. A X
Z B
Y
C
Since ∠B and ∠Y are right angles and AC ≅ XZ (hypotenuse of each triangle), AB ≅ YZ (corresponding leg of each triangle), then ∆ABC ≅∆XYZ by HL.
MIDDLE LEVEL MATH.
27
TEACHER CERTIFICATION STUDY GUIDE Example: What method would you use to prove the triangles congruent?
AAS
HL
MIDDLE LEVEL MATH.
28
TEACHER CERTIFICATION STUDY GUIDE The Pythagorean Theorem Given any right-angle triangle,  ABC , the square of the hypotenuse is equal to the sum of the squares of the other two sides. A
Hypotenuse (side opposite the 90 angle) side c
side b
C
B side a
This theorem says that ( = AB )2 (BC )2 + ( AC )2 or 2 2 c= a + b 2 Example:
Two cars leave a road intersection at the same time. One car travels due north at 55 mph while the other car travels due east. After 3 hours, the cars are 180 miles apart. Find the speed of the second car. Using a right triangle to represent the problem, we get the figure: A
North
165
Traveling at 55 mph for 3 hours, the northbound car has driven (55)(3)=165 miles. This is the side AC.
180
We are given that the cars are 180 miles apart. This is side AB. C Intersection (Point of origin) MIDDLE LEVEL MATH.
B
East 29
TEACHER CERTIFICATION STUDY GUIDE Since  ABC is a right triangle, then, by Pythagorean Theorem, we get: (= AB )2 (BC )2 + ( AC )2 or (BC = )2 ( AB )2 − ( AC )2
(BC = )2 1802 − 1652 (= BC )2 32400 − 27225 (BC )2 = 5175 Take the square root of (BC)2 to get:
= (BC )2
5175 ≈ 71.935 miles
Since the east bound car has traveled 71.937 miles in 3 hours, then the average speed is: 71.935 ≈ 23.97 mph 3
The key to applying the distance formula is to understand the problem before beginning. D=
( x2 − x1)2 + ( y 2 − y1)2
Sample Problem: 1. Find the perimeter of a figure with vertices at (4,5), ( − 4 ,6) and ( − 5, − 8 ). The figure being described is a triangle. Therefore, the distance for all three sides must be found. Carefully, identify all three sides before beginning. Side 1 = (4,5) to ( − 4,6) Side 2 = ( − 4,6) to ( − 5, − 8) Side 3 = ( − 5, − 8) to (4,5)
MIDDLE LEVEL MATH.
30
TEACHER CERTIFICATION STUDY GUIDE
D1 =
( −4 − 4)2 + (6 − 5)2 =
D2=
(( − 5 − ( − 4))2 + ( − 8 − 6)2=
197
D3=
((4 − ( − 5))2 + (5 − ( − 8)2=
250 or 5 10
65
Perimeter = 65 + 197 + 5 10 Midpoint Definition: If a line segment has endpoints of ( x1, y1 ) and ( x2 , y 2 ), then the midpoint can be found using: x1 + x2 y1 + y 2 2 , 2
Sample problems: 1. Find the center of a circle with a diameter whose endpoints are (3,7) and ( − 4, − 5 ). 3 + ( − 4) 7 + ( − 5) Midpoint = , 2 2 −1 Midpoint = ,1 2
(
)
(
)
2. Find the midpoint given the two points 5,8 6 and 9, − 4 6 . 5 + 9 8 6 + ( −4 6) Midpoint = 2 , 2
(
Midpoint = 7,2 6
MIDDLE LEVEL MATH.
)
31
TEACHER CERTIFICATION STUDY GUIDE The distance between two parallel lines, such as line AB and line CD as shown below is the line segment RS , the perpendicular between the two parallels. A
R
B
C
S
D
Sample Problem: Given the geometric figure below, find the distance between the two parallel sides AB and CD .
A
H
F 9
B
4
R
7
E
8
D
C G
The distance FG is 12 units.
MIDDLE LEVEL MATH.
32
TEACHER CERTIFICATION STUDY GUIDE Characteristics of a circle 1)
The radius, r, of a circle is the length of a line segment from the center to a point on the circle.
2)
The diameter, d, is the length of a line segment through the center of the circle with the end points on the circle.
3)
The circumference, c, is the distance around the circle.
4)
d = 2r
5)
Circumference is given by c = 2π r .( π is approximately 3.14)
6)
Area of the circle is given by A = π r 2 .
Example:
A city municipal pool has the shape and dimensions shown below. It has a uniform depth of 6 feet. A
I
7’
J
B
7’
20’
C
20’
H
G
E
The radius of the half circle JAB is 4 ft.
D
7’
7’
F a) b) c)
Find the perimeter in feet of the pool. Find the surface area of the pool in ft 2 . Find the volume of the pool in ft 3 .
Answer a.
MIDDLE LEVEL MATH.
Perimeter is the distance around the pool, or the total of JAB + BC + CD + DE + EFG + GH + HI + IJ . JAB is half a circle with radius of 4 feet. 1 (4)) 4π Circumference of JAB = EFG = ( 2π= 2 Perimeter = 4π + 7 + 20 + 7 + 4π + 7 + 20 + 7 = 68 '+ 8π ' Perimeter ≈ 93.135 feet.
33
TEACHER CERTIFICATION STUDY GUIDE Exercise: You have decided to fertilize your lawn. The shapes and dimensions of your lot, house, pool and garden are given in the diagram below. The shaded area will not be fertilized. If each bag of fertilizer costs $7.95 and covers 4,500 square feet, find the total number of bags needed and the total cost of the fertilizer. 160 ft. 80
20
50
20
100 25
20
10
180 ft. Area of Lot A = ½ h(b1 + b2 )
Area of House A = LW
A = ½ (100)(180 + 160) A = 17,000 sq ft
A = (80)(50) A = 4,000 sq ft
Area of Driveway A = LW A = (10)(25) A = 250 sq ft
Area of Pool A = πr2
Area of Garden A = s2
A = π (10)2 A = 314.159 sq. ft.
A = (20)2 A = 400 sq. ft.
Total area to fertilize = Lot area - (House + Driveway + Pool + Garden) = 17,000 - (4,000 + 250 + 314.159 + 400) = 12,035.841 sq ft Number of bags needed = Total area to fertilize = 12,035.841
4,500 sq.ft. bag
4,500
= 2.67 bags Since we cannot purchase 2.67 bags we must purchase 3 full bags. Total cost = Number of bags * $7.95 = 3 * $7.95 = $23.85
MIDDLE LEVEL MATH.
34
TEACHER CERTIFICATION STUDY GUIDE Competency 0007
Understand and use measurement.
Create an exercise to satisfy the requirements above. Exercise: Interpreting Slope as a Rate of Change Connection: Social Sciences/Geography Real-life Application: Slope is often used to describe a constant or average rate of change. These problems usually involve units of measure, such as miles per hour or dollars per year. Problem: The town of Verdant Slopes has been experiencing a boom in population growth. By the year 2000, the population had grown to 45,000, and by 2005, the population had reached 60,000. Communicating Algebra: a. Using the formula for slope as a model, find the average rate of change in population growth, expressing your answer in people per year. Extension: b. Using the average rate of change determined in a., predict the population of Verdant Slopes in the year 2010. Solution: a. Let t represent the time and p represent population growth. The two observances are represented by ( t1 , p1 ) and ( t2, p2 ). 1st observance = ( t1 , p1 ) = (2000, 45000) 2nd observance = ( t2 , p2 ) = (2005, 60000) Use the formula for slope to find the average rate of change. Rate of change =
MIDDLE LEVEL MATH.
p2 − p1 t2 − t1
35
TEACHER CERTIFICATION STUDY GUIDE Substitute values. =
60000 − 45000 2005 − 2000
Simplify. =
15000 = 3000 people / year 5
The average rate of change in population growth for Verdant Slopes between the years 2000 and 2005 was 3000 people/year. b.
3000 people / year × 5 years = 15000 people 60000 people + 15000 people = 75000 people
At a continuing average rate of growth of 3000 people/year, the population of Verdant Slopes could be expected to reach 75,000 by the year 2010.
MIDDLE LEVEL MATH.
36
TEACHER CERTIFICATION STUDY GUIDE Sample problems: 1. Find the area of one side of the metal in the circular flat washer shown below:
1. the shapes are both circles. 2. use the formula A = π r 2 for both.
1 1 " 2
(Inside diameter is 3 8" )
Area of larger circle
Area of smaller circle
A = π r2 A = π (.752 )
A = π r2 A = π (.18752 )
A = 1.76625 in2
A = .1103906 in2
Area of metal washer = larger area - smaller area = 1.76625 in2 − .1103906 in2 = 1.6558594 in2
MIDDLE LEVEL MATH.
37
TEACHER CERTIFICATION STUDY GUIDE Cut the compound shape into smaller, more familiar shapes and then compute the total area by adding the areas of the smaller parts. Sample problem: Find the area of the given shape. 5
12
7 8
6 1. Using a dotted line we have cut the shape into smaller parts that are familiar. 2. Use the appropriate formula for each shape and find the sum of all areas. Area 1 = LW = (5)(7) = 35 units
2
Area 2 = LW
Area 3 = ½bh
= (12)(8)
= ½(6)(8)
= 96 units
2
Total area = Area 1 + Area 2 + Area 3 = 35 + 96 + 24 = 155 units
MIDDLE LEVEL MATH.
2
38
= 24 units
2
TEACHER CERTIFICATION STUDY GUIDE CUSTOMARY SYSTEM The units of length in the customary system are inches, feet, yards and miles. 12 inches (in.) = 1 foot (ft.) 36 in. = 1 yard (yd.) 3 ft. = 1 yd. 5280 ft. = 1 mile (mi.) 1760 yd. = 1 mi. The units of weight are ounces, pounds and tons. 16 ounces (oz.) = 1 pound (lb.) 2,000 lb. = 1 ton (T.) The units of capacity are fluid ounces, cups, pints, quarts, and gallons. 8 fluid ounces (fl. oz.) = 1 cup (c.) 2 c. = 1 pint (pt.) 4 c. = 1 quart (qt.) 2 pt. = 1 qt. 4 qt. = 1 gallon (gal.) Square units can be derived with knowledge of basic units of length by squaring the equivalent measurements. 1 square foot (sq. ft.) = 144 sq. in. 1 sq. yd. = 9 sq. ft. 1 sq. yd. = 1296 sq. in. The metric system is based on multiples of ten. C onversions are made by simply moving the decimal point to the left or right. kilo- 1000 thousands hecto- 100 hundreds deca10 tens unit deci.1 tenths centi.01 hundredths milli.001 thousandths
MIDDLE LEVEL MATH.
39
TEACHER CERTIFICATION STUDY GUIDE Non-standard units are sometimes used when standard instruments might not be available. For example, students might measure the length of a room by their arm-spans. An inch originated as the length of three barley grains placed end to end. Seeds or stones might be used for measuring weight. In fact, our current “carat,” used for measuring precious gems, was derived from carob seeds. In ancient times, baskets, jars and bowls were used to measure capacity. To estimate measurement of familiar objects, it is first necessary to determine the units to be used. Examples: Length 1. The coastline of Florida 2. The width of a ribbon 3. The thickness of a book 4. The length of a football field 5. The depth of water in a pool
miles or kilometers inches or millimeters inches or centimeters yards or meters feet or meters
Weight or mass 1. A bag of sugar 2. A school bus 3. A dime
pounds or grams tons or kilograms ounces or grams
Capacity 1. Paint to paint a bedroom 2. Glass of milk 3. Bottle of soda 4. Medicine for child
gallons or liters cups or liters quarts or liters ounces or milliliters
Rounding measurements and conversions Rounding a measurement to the nearest unit desired is a quick way of making a mathematical estimate or approximation of that measurement. Measurements of length (English system) 12 inches (in) 3 feet (ft) 1760 yards (yd)
MIDDLE LEVEL MATH.
= = =
40
1 foot (ft) 1 yard (yd) 1 mile (mi)
TEACHER CERTIFICATION STUDY GUIDE Measurements of length (Metric system) kilometer (km) = 1000 meters (m) hectometer (hm) = 100 meters (m) decameter (dam) = 10 meters (m) meter (m) = 1 meter (m) decimeter (dm) = 1/10 meter (m) centimeter (cm) = 1/100 meter (m) millimeter (mm) = 1/1000 meter (m) Conversion of length from English to Metric 1 inch 1 foot 1 yard 1 mile
= ≈ ≈ ≈
2.54 centimeters 30.48 centimeters 0.91 meters 1.61 kilometers
Measurements of weight (English system) 28.35 grams (g) 16 ounces (oz) 2000 pounds (lb) 1.1 ton (t)
= = = =
1 ounce (oz) 1 pound (lb) 1 ton (t) (short ton) 1 metric ton (t)
Measurements of weight (Metric system) kilogram (kg) gram (g) milligram (mg)
= = =
1000 grams (g) 1 gram (g) 1/1000 gram (g)
Conversion of weight from English to metric 1 ounce 1 pound 1.1 ton
≈ ≈ =
28.35 grams 0.454 kilogram 1 metric ton
Measurement of volume (English system) 8 fluid ounces (oz) 2 cups (c) 2 pints (pt) 4 quarts (qt)
= = = =
1 cup (c) 1 pint (pt) 1 quart (qt) 1 gallon (gal)
Measurement of volume (Metric system) kiloliter (kl) liter (l) milliliter (ml)
MIDDLE LEVEL MATH.
= = =
41
1000 liters (l) 1 liter (l) 1/1000 liter (ml)
TEACHER CERTIFICATION STUDY GUIDE Conversion of volume from English to metric 1 teaspoon (tsp) 1 fluid ounce 1 cup 1 pint 1 quart 1 gallon
≈ ≈ ≈ ≈ ≈ ≈
5 milliliters 15 29.56 milliliters 0.24 liters 0.47 liters 0.95 liters 3.8 liters
Note: ( ‘ ) represents feet and ( “ ) represents inches. Most numbers in mathematics are "exact" or "counted". Measurements are "approximate". They usually involve interpolation or figuring out which mark on the ruler is closest. Any measurement you get with a measuring device is approximate. Variations in measurement are called precision and accuracy. Precision is a measurement of how exactly a measurement is made, without reference to a true or real value. If a measurement is precise it can be made again and again with little variation in the result. The precision of a measuring device is the smallest fractional or decimal division on the instrument. The smaller the unit or fraction of a unit on the measuring device, the more precisely it can measure. The greatest possible error of measurement is always equal to onehalf the smallest fraction of a unit on the measuring device. Accuracy is a measure of how close the result of measurement comes to the "true" value. If you are throwing darts, the true value is the bull's eye. If the three darts land on the bull's eye, the dart thrower is both precise (all land near the same spot) and accurate (the darts all land on the "true" value). The greatest measure of error allowed is called the tolerance. The least acceptable limit is called the lower limit and the greatest acceptable limit is called the upper limit. The difference between the upper and lower limits is called the tolerance interval. For example, a specification for an automobile part might be 14.625 ± 0.005 mm. This means that the smallest acceptable length of the part is 14.620 mm and the largest length acceptable is 14.630 mm. The tolerance interval is 0.010 mm. One can see how it would be important for automobile parts to be within a set of limits in terms of length. If the part is too long or too short it will not fit properly and vibrations will occur weakening the part and eventually causing damage to other parts.
MIDDLE LEVEL MATH.
42
TEACHER CERTIFICATION STUDY GUIDE Use the formulas to find the volume and surface area. FIGURE Right Cylinder
VOLUME π r 2h π r 2h 3 4 3 πr 3 LWH
Right Cone Sphere Rectangular Solid
TOTAL SURFACE AREA 2π rh + 2π r 2
π r r 2 + h2 + π r 2 4π r 2 2LW + 2WH + 2LH
r 2 + h 2 is equal to the slant height of the cone.
Note:
Sample problem: 1. Given the figure below, find the volume and surface area. h = r 5= in h 6.2 in r
πr h 2
Volume =
First write the formula.
3
1 π (52 )(6.2) 3 162.3 cubic inches
Then substitute. Finally solve the problem.
Surface area = π r r 2 + h 2 + π r 2
π 5 52 + 6.22 + π 52 203.6 square inches
First write the formula. Then substitute. Compute.
Note: volume is always given in cubic units and area is always given in square units. FIGURE Rectangle Triangle Parallelogram Trapezoid
MIDDLE LEVEL MATH.
AREA FORMULA LW 1 bh 2 bh 1 h(a + b ) 2
43
PERIMETER FORMULA 2(L + W ) a+b+c
sum of lengths of sides sum of lengths of sides
TEACHER CERTIFICATION STUDY GUIDE Sample problems: 1. Find the area and perimeter of a rectangle if its length is 12 inches and its diagonal is 15 inches. 1. Draw and label sketch. 2. Since the height is still needed use Pythagorean formula to find missing leg of the triangle.
C 15
A
A2 + B 2 = C2 A2 + 122 = 152 = A2 152 − 122 A2 = 81 A=9
12 B
Now use this information to find the area and perimeter. A = LW A = (12)(9)
P 2(L + W ) = P = 2(12 + 9)
A = 108 in 2
P = 42 inches
MIDDLE LEVEL MATH.
44
1. write formula 2. substitute 3. solve
TEACHER CERTIFICATION STUDY GUIDE Given a circular figure the formulas are as follows: A= πr2
C = πd
or 2π r
Sample problem: 1. If the area of a circle is 50 cm 2 , find the circumference. 1. Draw sketch. r
A = 50 cm
2
2. Determine what is still needed.
Use the area formula to find the radius. A= πr 2 50 = π r 2 50 = r2
1. write formula 2. substitute 3. divide by π
π 15.915 = r 2
4. substitute
15.915 = r 2 3.989 ≈ r
5. take square root of both sides 6. compute
Use the approximate answer (due to rounding) to find the circumference. C = 2π r C = 2π (3.989) C ≈ 25.064
MIDDLE LEVEL MATH.
1. write formula 2. substitute 3. compute
45
TEACHER CERTIFICATION STUDY GUIDE Use appropriate problem solving strategies to find the solution. 12 1. Find the area of the given figure. 5 4
7
2. Cut the figure into familiar shapes.
8 3
3. Identify what type figures are given and write the appropriate formulas.
7 Area of figure 1 (triangle) 1 A = bh 2 1 A = (8)(4) 2 A = 16 sq. ft
Area of figure 2 (parallelogram) A = bh A = (7)(3) A = 21 sq. ft
Area of figure 3 (trapezoid) 1 A = h(a + b ) 2 1 = (5)(12 + 7) A 2 A = 47.5 sq. ft
Now find the total area by adding the area of all figures. Total area = 16 + 21 + 47.5 Total area = 84.5 square ft
MIDDLE LEVEL MATH.
46
TEACHER CERTIFICATION STUDY GUIDE FIGURE Right prism
LATERAL AREA Ph
Regular Pyramid
TOTAL AREA 2B+Ph
1/2Pl
VOLUME Bh
1/2Pl+B
1/3Bh
P = Perimeter h = height B = Area of Base l = slant height Find the total area of the given figure:
4
1.
Since this is a triangular prism, first find the area of the bases.
2.
Find the area of each rectangular lateral face.
3.
Add the areas together.
4
12
12 8
8
4
4
1 bh 2 2 8= 42 + h 2 h = 6.928 1 A = (8)(6.928) 2
A = LW
A = 27.713 sq. units
A = 96 sq. units
A=
2. find the height of the base triangle A = (8)(12)
Total Area = 2(27.713) + 3(96) = 343.426 sq. units
MIDDLE LEVEL MATH.
1. write formula
47
3. substitute known values 4. compute
TEACHER CERTIFICATION STUDY GUIDE FIGURE
VOLUME
TOTAL SURFACE LATERAL AREA AREA 2π rh + 2π r 2 2π rh
π r 2h
Right Cylinder
π r 2h
Right Cone
π r r 2 + h2 + π r 2
3
π r r 2 + h2
r 2 + h 2 is equal to the slant height of the cone.
Note:
Sample problem: 1. A water company is trying to decide whether to use traditional cylindrical paper cups or to offer conical paper cups since both cost the same. The traditional cups are 8 cm wide and 14 cm high. The conical cups are 12 cm wide and 19 cm high. The company will use the cup that holds the most water. 1. Draw and label a sketch of each. 12
14
19
8
π r 2h
V = π r 2h
V=
V = π (4)2 (14)
1 π (6)2 (19) 3 V = 716.283 cm 3
V = 703.717 cm 3
V=
3
1. write formula 2. substitute 3. solve
The choice should be the conical cup since its volume is more.
MIDDLE LEVEL MATH.
48
TEACHER CERTIFICATION STUDY GUIDE FIGURE Sphere
VOLUME 4 3 πr 3
TOTAL SURFACE AREA
4π r 2
Sample problem: 1. How much material is needed to make a basketball that has a diameter of 15 inches? How much air is needed to fill the basketball? Draw and label a sketch:
D=15 inches
Total surface area TSA = 4π r 2 = 4π (7.5)2
= 706.9 in 2
MIDDLE LEVEL MATH.
Volume 4 3 πr 3 4 = π (7.5)3 3 = 1767.1 in 3
V=
49
1. write formula 2. substitute 3. solve
TEACHER CERTIFICATION STUDY GUIDE SUBAREA IV. DATA ANALYSIS, STATISTICS, AND PROBABILITY Competency 0008
Understand methods of collecting, organizing, displaying, describing, and analyzing data.
Observation-inference is a mathematic process skill that is used regularly in statistics. We can use the data gathered or observed from a sample of the population to make inferences about traits and qualities of the population as a whole. For example, if we observe that 40% of voters in our sample favor Candidate A, then we can infer that 40% of the entire voting population favors Candidate A. Successful use of observation-inference depends on accurate observation and representative sampling. Random sampling is the process of studying an aspect of a population by selecting and gathering data from a segment of the population and making inferences and generalizations based on the results. Two main types of random sampling are simple and stratified. With simple random sampling, each member of the population has an equal chance of selection to the sample group. With stratified random sampling, each member of the population has a known but unequal chance of selection to the sample group, as the study selects a random sample from each population demographic. In general, stratified random sampling is more accurate because it provides a more representative sample group. Sample statistics are important generalizations about the entire sample such as mean, median, mode, range, and sampling error (standard deviation). Various factors affect the accuracy of sample statistics and the generalizations made from them about the larger population. Sample size is one important factor in the accuracy and reliability of sample statistics. As sample size increases, sampling error (standard deviation) decreases. Sampling error is the main determinant of the size of the confidence interval. Confidence intervals decrease in size as sample size increases. A confidence interval gives an estimated range of values, which is likely to include a particular population parameter. The confidence level associated with a confidence interval is the probability that the interval contains the population parameter. For example, a poll reports that 60% of a sample group prefers candidate A with a margin of error of + 3% and a confidence level of 95%. In this poll, there is a 95% chance that the preference for candidate A in the whole population is between 57% and 63%.
MIDDLE LEVEL MATH.
50
TEACHER CERTIFICATION STUDY GUIDE The ultimate goal of sampling is to make generalizations about a population based on the characteristics of a random sample. Estimators are sample statistics used to make such generalizations. For example, the mean value of a sample is the estimator of the population mean. Unbiased estimators, on average, accurately predict the corresponding population characteristic. Biased estimators, on the other hand, do not exactly mirror the corresponding population characteristic. While most estimators contain some level of bias, limiting bias to achieve accurate projections is the goal of statisticians. The law of large numbers and the central limit theorem are two fundamental concepts in statistics. The law of large numbers states that the larger the sample size, or the more times we measure a variable in a population, the closer the sample mean will be to the population mean. For example, the average weight of 40 apples out of a population of 100 will more closely approximate the population average weight than will a sample of 5 apples. The central limit theorem expands on the law of large numbers. The central limit theorem states that as the number of samples increases, the distribution of sample means (averages) approaches a normal distribution. This holds true regardless of the distribution of the population. Thus, as the number of samples taken increases, the sample mean becomes closer to the population mean. This property of statistics allows us to analyze the properties of populations of unknown distribution. In conclusion, the law of large numbers and central limit theorem show the importance of large sample size and large number of samples to the process of statistical inference. As sample size and the number of samples taken increase, the accuracy of conclusions about the population drawn from the sample data increases.
MIDDLE LEVEL MATH.
51
TEACHER CERTIFICATION STUDY GUIDE An understanding of the definitions is important in determining the validity and uses of statistical data. All definitions and applications in this section apply to ungrouped data. Data item: each piece of data is represented by the letter X . Mean: the average of all data represented by the symbol X . Range: difference between the highest and lowest value of data items. Sum of the Squares: sum of the squares of the differences between each item and the mean. 2 Sx= ( X − X )2
Variance: the sum of the squares quantity divided by the number of items. (the lower case Greek letter sigma ( σ ) squared represents variance). Sx 2 =σ2 N The larger the value of the variance the larger the spread
small variation
larger variation
Standard Deviation: the square root of the variance. The lower case Greek letter sigma ( σ ) is used to represent standard deviation. σ = σ2 Most statistical calculators have standard deviation keys on them and should be used when asked to calculate statistical functions. It is important to become familiar with the calculator and the location of the keys needed. Sample Problem: Given the ungrouped data below, calculate the mean, range, standard deviation and the variance. 15 18
22 25
28 30
25 33
Mean ( X ) = 25.8333333 23 Range: 38 − 15 = standard deviation (σ ) = 6.699137 Variance (σ 2 ) = 48.87879 MIDDLE LEVEL MATH.
52
34 19
38 23
TEACHER CERTIFICATION STUDY GUIDE Percentiles divide data into 100 equal parts. A person whose score falls in the 65th percentile has outperformed 65 percent of all those who took the test. This does not mean that the score was 65 percent out of 100 nor does it mean that 65 percent of the questions answered were correct. It means that the grade was higher than 65 percent of all those who took the test. Stanine “standard nine” scores combine the understandability of percentages with the properties of the normal curve of probability. Stanines divide the bell curve into nine sections, the largest of which stretches from the 40th to the 60th percentile and is the “Fifth Stanine” (the average of taking into account error possibilities).
Average Below Average
Above Average
Higher
Lower 4%
7%
12% 17% 20% 17% 12% 7%
STANINE 5 6 1 2 7 3 4 PERCENTILE 4 11 23 40 60 77 89
4%
8
9 96
Quartiles divide the data into 4 parts. First find the median of the data set (Q2), then find the median of the upper (Q3) and lower (Q1) halves of the data set. If there are an odd number of values in the data set, include the median value in both halves when finding quartile values. For example, given the data set: {1, 4, 9, 16, 25, 36, 49, 64, 81} first find the median value, which is 25 (this is the second quartile). Since there are an odd number of values in the data set (9), we include the median in both halves. To find the quartile values, we much find the medians of: {1, 4, 9, 16, 25} and {25, 36, 49, 64, 81}. Since each of these subsets had an odd number of elements (5), we use the middle value. Thus the first quartile value is 9 and the third quartile value is 49. If the data set had an even number of elements, average the middle two values. The quartile values are always either one of the data points, or exactly half way between two data points.
MIDDLE LEVEL MATH.
53
TEACHER CERTIFICATION STUDY GUIDE Sample problem: 1. Given the following set of data, find the percentile of the score 104. [70, 72, 82, 83, 84, 87, 100, 104, 108, 109, 110, 115] Solution: Find the percentage of scores below 104. 7/12 of the scores are less than 104. This is 58.333%; therefore, the score of 104 is in the 58th percentile. 2. Find the first, second and third quartile for the data listed. 6, 7, 8, 9, 10, 12, 13, 14, 15, 16, 18, 23, 24, 25, 27, 29, 30, 33, 34, 37 Quartile 1:
The 1st Quartile is the median of the lower half of the data set, which is 11.
Quartile 2:
The median of the data set is the 2nd Quartile, which is 17.
Quartile 3:
The 3rd Quartile is the median of the upper half of the data set, which is 28.
Mean, median and mode are three measures of central tendency. The mean is the average of the data items. The median is found by putting the data items in order from smallest to largest and selecting the item in the middle (or the average of the two items in the middle). The mode is the most frequently occurring item. Range is a measure of variability. It is found by subtracting the smallest value from the largest value. Sample problem: Find the mean, median, mode and range of the test score listed below: 85 92 88 75 85 72
77 90 85 80 88 74
MIDDLE LEVEL MATH.
65 54 70 69 60 95
54
TEACHER CERTIFICATION STUDY GUIDE Mean (X) = sum of all scores ÷ number of scores = 78 Median = put numbers in order from smallest to largest. Pick middle number. 54, 60, 65, 69, 70, 72, 74, 75, 77, 80, 85, 85, 85, 88, 88, 90, 92, 95 -Â� -Â� both in middle Therefore, median is average of two numbers in the middle or 78.5 Mode = most frequent number = 85 Range = largest number minus the smallest number = 95 − 54 = 41 Different situations require different information. If we examine the circumstances under which an ice cream store owner may use statistics collected in the store, we find different uses for different information. Over a 7-day period, the store owner collected data on the ice cream flavors sold. He found the mean number of scoops sold was 174 per day. The most frequently sold flavor was vanilla. This information was useful in determining how much ice cream to order in all, and in what amounts for each flavor. In the case of the ice cream store, the median and range had little business value for the owner. Consider the set of test scores from a math class: 0, 16, 19, 65, 65, 65, 68, 69, 70, 72, 73, 73, 75, 78, 80, 85, 88, and 92. The mean is 64.06 and the median is 71. Since there are only three scores less than the mean out of the eighteen scores, the median (71) would be a more descriptive score. Retail store owners may be most concerned with the most common dress size, so they may order more of that size than any other.
MIDDLE LEVEL MATH.
55
TEACHER CERTIFICATION STUDY GUIDE To make a bar graph or a pictograph, determine the scale to be used for the graph. Then determine the length of each bar on the graph or determine the number of pictures needed to represent each item of information. Be sure to include an explanation of the scale in the legend. Example:
A class had the following grades: 4 A's, 9 B's, 8 C's, 1 D, 3 F's. Graph these on a bar graph and a pictograph.
Pictograph Grade
Number of Students
A B C D F
Bar graph
MIDDLE LEVEL MATH.
56
TEACHER CERTIFICATION STUDY GUIDE To make a line graph, determine appropriate scales for both the vertical and horizontal axes (based on the information to be graphed). Describe what each axis represents and mark the scale periodically on each axis. Graph the individual points of the graph and connect the points on the graph from left to right. Line graphs are sometimes referred to as frequency polygons. Example: Graph the following information using a line graph. The number of National Merit finalists/school year 90-'91 91-'92 92-'93 93-'94 94-'95 95-'96 Central 3 5 1 4 6 8 Wilson 4 2 3 2 3 2
9 8
Number of Students
7 6 5
Central
4
Wilson
3 2 1 0 90-'91
91-'92
92-'93
93-'94
94-'95
95-'96
Year
To make a circle graph, total all the information that is to be included on the graph. Determine the central angle to be used for each sector of the graph using the following formula: information degrees in central ï†fi × 360° = total information
Lay out the central angles to these sizes, label each section and include its percentage.
MIDDLE LEVEL MATH.
57
TEACHER CERTIFICATION STUDY GUIDE Example: Graph this information on a circle graph: Monthly expenses: Rent, Food, Utilities Clothes Church Misc.
$400 $150 $75 $75 $100 $200 Misc 20%
Rent 39% Church 10%
Clothes 7.5% Utilities 7.5%
Food 15%
A circle graph, also known as a pie chart, is used to represent relative amounts of a whole. To read a bar graph or a pictograph, read the explanation of the scale that was used in the legend. Compare the length of each bar with the dimensions on the axes and calculate the value each bar represents. On a pictograph count the number of pictures used in the chart and calculate the value of all the pictures. To read a circle graph, find the total of the amounts represented on the entire circle graph. To determine the actual amount that each sector of the graph represents, multiply the percent in a sector times the total amount number. To read a chart read the row and column headings on the table. Use this information to evaluate the given information in the chart.
MIDDLE LEVEL MATH.
58
TEACHER CERTIFICATION STUDY GUIDE
Weekly Salary
Scatter plots compare two characteristics of the same group of things or people and usually consist of a large body of data. They show how much one variable is affected by another. The relationship between the two variables is their correlation. The closer the data points come to making a straight line when plotted, the closer the correlation. 950 900 850 800 750 700 650 600 0
2
4
6
8
Years of Experience
Stem and leaf plots are visually similar to line plots. The stems are the digits in the greatest place value of the data values, and the leaves are the digits in the next greatest place values. Stem and leaf plots are best suited for small sets of data and are especially useful for comparing two sets of data. The following is an example using test scores: 4 5 6 7 8 9 10
MIDDLE LEVEL MATH.
9 4 1 0 3 0 0
9 2 3 5 0 0
3 4 5 3
4 6 7 4
6 7 8 8 6 6 7 7 7 7 8 8 8 8 8 5
59
TEACHER CERTIFICATION STUDY GUIDE Histograms are used to summarize information from large sets of data that can be naturally grouped into intervals. The vertical axis indicates frequency (the number of times any particular data value occurs), and the horizontal axis indicates data values or ranges of data values. The number of data values in any interval is the frequency of the interval. 5
Frequency
4 3 2 1
0 600
625
650
675
700
725
Weekly Salaries
MIDDLE LEVEL MATH.
60
TEACHER CERTIFICATION STUDY GUIDE Competency 0009
Understand the theory of probability and probability distributions.
In probability, the sample space is a list of all possible outcomes of an experiment. For example, the sample space of tossing two coins is the set {HH, HT, TT, TH}, the sample space of rolling a sixsided die is the set {1, 2, 3, 4, 5, 6}, and the sample space of measuring the height of students in a class is the set of all real numbers {R}. When conducting experiments with a large number of possible outcomes it is important to determine the size of the sample space. The size of the sample space can be determined by using the fundamental counting principle and the rules of combinations and permutations. The fundamental counting principle states that if there are m possible outcomes for one task and n possible outcomes of another, there are (m x n) possible outcomes of the two tasks together. A permutation is the number of possible arrangements of items, without repetition, where order of selection is important. A combination is the number of possible arrangements, without repetition, where order of selection is not important. Examples: 1. Find the size of the sample space of rolling two six-sided die and flipping two coins. Solution: List the possible outcomes of each event: each dice: {1, 2, 3, 4, 5, 6} each coin: {Heads, Tails} Apply the fundamental counting principle: size of sample space = 6 x 6 x 2 x 2 = 144
MIDDLE LEVEL MATH.
61
TEACHER CERTIFICATION STUDY GUIDE Probability measures the chances of an event occurring. The probability of an event that must occur, a certain event, is one. When no outcome is favorable, the probability of an impossible event is zero. number of P(event) = number of
favorable outcomes possible outcomes
Example: Given one die with faces numbered 1 - 6, the probability of tossing an even number on one throw of the die is 63 or 21 since there are 3 favorable outcomes (even faces) and a total of 6 possible outcomes (faces). If A and B are independent events then the probability both A and B will occur is the product of their individual probabilities. Example 1: Given two dice, the probability of tossing a 3 on each of them simultaneously is the probability of a 3 on the first die, or 16 , times the probability of tossing a 3 on the second die, also
1 6
.
1 1 1 6 × 6 = 36
Example 2: A jar contains 10 marbles: 3 red, 5 black, and 2 white. What is the probability of drawing a red marble and then a white marble if the first marble is returned to the jar after choosing? 2 3 10 × 10
6
3
= 100 = 50
MIDDLE LEVEL MATH.
62
TEACHER CERTIFICATION STUDY GUIDE The absolute probability of some events cannot be determined. For instance, one cannot assume the probability of winning a tennis match is ½ because, in general, winning and losing are not equally likely. In such cases, past results of similar events can be used to help predict future outcomes. The relative frequency of an event is the number of times an event has occurred divided by the number of attempts. Relative frequency =
number of successful trials total number of trials
For example, if a weighted coin flipped 50 times lands on heads 40 times and tails 10 times, the relative frequency of heads is 40/50 = 4/5. Thus, one can predict that if the coin is flipped 100 times, it will land on heads 80 times. Example: Two tennis players, John and David, have played each other 20 times. John has won 15 of the previous matches and David has won 5. (a) Estimate the probability that David will win the next match. (b) Estimate the probability that John will win the next 3 matches. Solution: (a) David has won 5 out of 20 matches. Thus, the relative frequency of David winning is 5/20 or ¼. We can estimate that the probability of David winning the next match is ¼. (b) John has won 15 out of 20 matches. The relative frequency of John winning is 15/20 or ¾. We can estimate that the probability of John winning a future match is ¾. Thus, the probability that John will win the next three matches is ¾ x ¾ x ¾ = 27/64.
MIDDLE LEVEL MATH.
63
TEACHER CERTIFICATION STUDY GUIDE SUB-AREA V. PATTERNS, ALGEBRAIC RELATIONSHIPS, AND FUNCTIONS Competency 0010
Describe, analyze, and generalize mathematical patterns.
Kepler discovered a relationship between the average distance of a planet from the sun and the time it takes the planet to orbit the sun. The following table shows the data for the six planets closest to the sun:
Average distance, x x3 Time, y y2
Mercury Venus Earth Mars Jupiter 0.387 0.723 1 1.523 5.203 0.058 0.241 0.058
.378 0.615 0.378
1 1 1
Saturn 9.541
3.533 140.852 868.524 1.881 11.861 29.457 3.538 140.683 867.715
Looking at the data in the table, we can assume that x 3 ï•» y 2 . We can conjecture the following function for Kepler’s relationship: y = x3 The iterative process involves repeated use of the same steps. A recursive function is an example of the iterative process. A recursive function is a function that requires the computation of all previous terms in order to find a subsequent term. Perhaps the most famous recursive function is the Fibonacci sequence. This is the sequence of numbers 1,1,2,3,5,8,13,21,34 … for which the next term is found by adding the previous two terms. Example: Find the recursive formula for the sequence 1, 3, 9, 27, 81… We see that any term other than the first term is obtained by multiplying the preceding term by 3. Then, we may express the formula in symbolic notation as = an 3= an −1 , a1 1 , where a represents a term, the subscript n denotes the place of the term in the sequence and the subscript n − 1 represents the preceding term.
MIDDLE LEVEL MATH.
64
TEACHER CERTIFICATION STUDY GUIDE When using geometric sequences consecutive numbers are compared to find the common ratio.
r=
an +1 an
r = the common ratio an = the n th term The ratio is then used in the geometric sequence formula:
an = a1r n −1 Sample problems: 1. Find the 8th term of the geometric sequence 2, 8, 32, 128 ... r =
an +1 an
r =
8 2
Use the common ratio formula to find ratio.
Substitute an = 2
an +1 = 8
r=4
an= a1 × r n −1
Use r = 4 to solve for the 8th term.
a8= 2 × 48−1 a8 = 32768
MIDDLE LEVEL MATH.
65
TEACHER CERTIFICATION STUDY GUIDE Sequences can be finite or infinite. A finite sequence is a sequence whose domain consists of the set {1, 2, 3, … n} or the first n positive integers. An infinite sequence is a sequence whose domain consists of the set {1, 2, 3, …}; which is in other words all positive integers. A recurrence relation is an equation that defines a sequence recursively; in other words, each term of the sequence is defined as a function of the preceding terms. A real-life application would be using a recurrence relation to determine how much your savings would be in an account at the end of a certain period of time. For example: You deposit $5,000 in your savings account. Your bank pays 5% interest compounded annually. How much will your account be worth at the end of 10 years? Let V represent the amount of money in the account and Vn represent the amount of money after n years. The amount in the account after n years equals the amount in the account after n – 1 years plus the interest for the nth year. This can be expressed as the recurrence relation V0 where your initial deposit is represented by V0 = 5, 000 . V0 = V0 V1 = 1.05V0 = V2 1.05 = V1 (1.05) 2 V0 = V3 1.05 = V2 (1.05)3V0 ...... = Vn (1.05) = Vn −1 (1.05) n V0
Inserting the values into the equation, you get 10 = V10 (1.05) = (5, 000) 8,144 . You determine that after investing $5,000 in an account earning 5% interest, compounded annually for 10 years, you would have $8,144.
MIDDLE LEVEL MATH.
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TEACHER CERTIFICATION STUDY GUIDE Competency 0011
Use variables and symbolic expressions to describe and analyze patterns of change, functions, and relationships among variables.
An algebraic formula is an equation that describes a relationship among variables. While it is not often necessary to derive the formula, one must know how to rewrite a given formula in terms of a desired variable. Example:
The relationship of voltage, V, applied across a material with electrical resistance, R, when a current, I, is flowing through the material is given by the formula V = IR. Find the resistance of the material when a current of 10 milliamps is flowing, when the applied voltage is 2 volts.
V = IR. Solve for R. IR = V; R = V/I
Divide both sides by I. When V = 2 volts; I = 10 × 10
R= R=
−
3
amps; find R.
2 10 × 10 2 1
10
−
−
3
Substituting in R = V/I, we get,
2
R= 2 × 102 R = 200 ohms
Example:
Given the formula I = PRT, where I is the simple interest to be paid or realized when an amount P, the principal is to be deposited at simple interest rate of R (in %) and T is the time expressed in years, find what principal must be deposited to yield an interest of $586.00 over a period of 2 years at interest of 23.5%.
I RT I = 586; R = 23.5% = 0.235; T = 2 586 586 = P = 0.235 × 2 0.47 586 = P = 1246.80 = $1246.80 0.47
I = PRT
Solve for P P =
(Divide both sides by RT)
Substitute.
Check; I = PRT; 1246.8 ×0.235 × 2 = 586 MIDDLE LEVEL MATH.
67
TEACHER CERTIFICATION STUDY GUIDE Example:
= C
Given that temperature in Celsius (C), and Fahrenheit (F) are related by the formula:
5 (F − 32) , solve for F. 9
C 5(F − 32) = → 9C = 5F − 160 1 9
5= F 9C + 160 9C + 160 9C 160 = F = + 5 5 5 = F
9C + 32 5
Example:
The distance around a rectangular object, P (P=perimeter) is given by P = 2L + 2W, where L = length and W = width. Find what the width must be if the length is to be 46 feet and the perimeter is to be 108 feet.
= P 2L + 2W P − 2L = 2L + 2W − 2L
Subtract 2L from both sides.
2W P − 2L P − 2L = →W = 2 2 2
Divide both sides by 2.
= P 108; = L 46 = W
108 − 2(46) 108 − 92 16 = = 2 2 2
W = 8 feet.
MIDDLE LEVEL MATH.
68
TEACHER CERTIFICATION STUDY GUIDE Loosely speaking, an equation like = y 3 x + 5 describes a relationship between the independent variable x and the dependent variable y. Thus, y is written as f(x) “function of x.” But y may not be a “true” function. For a “true” function to exist, there is a relationship between a set of all independent variables (domain) and a set of all outputs or dependent variables (range) such that each element of the domain corresponds to one element of the range. (For any input we get exactly one output). Example: f
h
2
4
16
4
4
12
49
-4
8
16
81
9
Domain, X
Range, Y
Domain, X
This is a “true” function. Example:
Range, Y
This is not a “true” function.
Given a function f ( x= ) 3 x + 5 , find f (2); f (0); f ( − 10)
f (2) means find the value of the function value at x = 2. f (2) = 3(2) + 5 = 6 + 5 = 11 f (0) = 3(0) + 5 = 0 + 5 = 5 f ( − 10)= 3( − 10) + 5= Example:
−
30 + 5=
Substitute for x. −
25
Given h(t )= 3t 2 + t − 9 , find h( − 4) . − h(= 4) 3( − 4)2 − 4 − 9
h= ( − 4) 3(16) − 13 h( − 4) = 48 − 13 h( − 4) = 35
MIDDLE LEVEL MATH.
69
Substitute for t.
TEACHER CERTIFICATION STUDY GUIDE Example:
Given g ( x ) = 5 x 3 − 2 x 2 + 6 , find g (π 2 ) . g (π 2 ) = 5(π 2 )3 − 2(π 2 )2 + 6 g (π 2 ) = 5π 6 − 2π 4 + 6
Example:
2s 2 − 3 , find R( 2) . Given R(s ) = s
R( 2) =
2
( 2)
2
−3
2 2(2) − 3 R( 2) = 2 4−3 R( 2) = 2 1 2 R( = 2) × 2 2
R( 2) =
Example:
MIDDLE LEVEL MATH.
Substitute for x.
Substitute for s.
Rationalize the radical denominator.
2 2
3x 2 + 7 , find f ( − 2) . x−2 − 2 3( 2) + 7 f ( − 2) = −2 − 2 3(4) + 7 Substitute for x. f ( − 2) = −4 12 + 7 19 = f ( − 2) = −4 −4 19 f ( − 2) = −4
Given f ( x ) =
70
TEACHER CERTIFICATION STUDY GUIDE A linear function is a function defined by the equation f ( x= ) mx + b . Example: A model for the distance traveled by a migrating monarch butterfly looks like f (t ) = 80t , where t represents time in days. We interpret this to mean that the average speed of the butterfly is 80 miles per day and distance traveled may be computed by substituting the number of days traveled for t . In a linear function, there is a constant rate of change. The standard form of a quadratic function is f ( x) = ax 2 + bx + c . Example: What patterns appear in a table for y = x 2 − 5 x + 6 ? x 0 1 2 3 4 5
y 6 2 0 0 2 6
We see that the values for y are symmetrically arranged. An exponential function is a function defined by the equation y = ab x , where a is the starting value, b is the growth factor, and x tells how many times to multiply by the growth factor. Example: y = 100(1.5) x x 0 1 2 3 4
y 100 150 225 337.5 506.25
This is an exponential or multiplicative pattern of growth.
MIDDLE LEVEL MATH.
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TEACHER CERTIFICATION STUDY GUIDE - A relation is any set of ordered pairs. - The domain of a relation is the set made of all the first coordinates of the ordered pairs. - The range of a relation is the set made of all the second coordinates of the ordered pairs. - A function is a relation in which different ordered pairs have different first coordinates. (No x values are repeated.) - A mapping is a diagram with arrows drawn from each element of the domain to the corresponding elements of the range. If 2 arrows are drawn from the same element of the domain, then it is not a function. - On a graph, use the vertical line test to look for a function. If any vertical line intersects the graph of a relation in more than one point, then the relation is not a function.
1. Determine the domain and range of this mapping. ANSWERS 4
6
domain: {4, -5 }
-5
8 11
range : {6, 8, 11 }
2. Determine which of these are functions: a.
{(1,
−
}
4),(27,1)(94,5)(2, − 4)
b. f( x= ) 2x − 3 c. A=
{( x, y ) xy=
}
24
d. y = 3 e. x = − 9 f.
{(3,2),(7,7),(0,5),(2,
MIDDLE LEVEL MATH.
72
−
}
4),(8, − 6),(1,0),(5,9),(6, − 4)
TEACHER CERTIFICATION STUDY GUIDE 3. Determine the domain and range of this graph. 10
8
6
4
2
0 -10
-8
-6
-4
-2
0
2
4
6
-2
-4
-6
-8
-10
{
}
4. If A = ( x, y ) y = x 2 − 6 , find the domain and range. 5. Give the domain and range of set B if:
{
}
B = (1, − 2),(4, − 2),(7, − 2),(6, − 2)
6. Determine the domain of this function: f( x ) =
MIDDLE LEVEL MATH.
5x + 7 x2 − 4
73
8
10
TEACHER CERTIFICATION STUDY GUIDE 7. Determine the domain and range of these graphs. 10 8 6 4 2 0 -10
-8
-6
-4
-2
-2
0
2
4
6
8
8
10
10
-4 -6 -8 -10
10 8 6 4 2 0 -10
-8
-6
-4
-2
-2
0
2
4
6
-4 -6 -8 -10
8. If= E
y 5} , find the domain and range. {( x, y ) =
9. Determine the ordered pairs in the relation shown in this mapping.
3
9
-4
16
6
3
1
MIDDLE LEVEL MATH.
74
TEACHER CERTIFICATION STUDY GUIDE If f ( x ) is a function and the value of 3 is in the domain, the corresponding element in the range would be f(3). It is found by evaluating the function for x = 3 . The same holds true for adding, subtracting, and multiplying in function form. −
The symbol f 1 is read “the inverse of f”. The −1 is not an exponent. The inverse of a function can be found by reversing the order of coordinates in each ordered pair that satisfies the function. Finding the inverse functions means switching the place of x and y and then solving for y . Sample problem: 1. Find p (a + 1) + 3{p(4a )} if p ( x )= 2 x 2 + x + 1. Find p (a + 1) . p (a + 1)= 2(a + 1)2 + (a + 1) + 1
Substitute (a + 1) for x .
p (a + 1)= 2a 2 + 5a + 4
Solve.
Find 3{p(4a )} . 3{p(4a= )} 3[2(4a )2 + (4a ) + 1] 3{p(4a )} = 96a2 + 12a + 3
Substitute (4a ) for x , multiply by 3. Solve.
p (a + 1) + 3{p(4a )}= 2a2 + 5a + 4 + 96a2 + 12a + 3 Combine like terms. p(a + 1) + 3{p(4a= )} 98a2 + 17a + 7
When graphing a first-degree equation, solve for the variable. The graph of this solution will be a single point on the number line. There will be no arrows. When graphing a linear inequality, the dot will be hollow if the inequality sign is < or >. If the inequality signs is either ≥ or ≤ , the dot on the graph will be solid. The arrow goes to the right for ≥ or >. The arrow goes to the left for < or ≤ .
MIDDLE LEVEL MATH.
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TEACHER CERTIFICATION STUDY GUIDE Example:
5( x + 2 ) + 2x = 3( x – 2 ) 5x + 10 + 2x = 3x – 6 7x + 10 = 3x – 6 4x = –16 x = –4
-10 -8 -6 -4 -2 0 2 4 6 8 10 Example:
2( 3x – 7 ) > 10x – 2 6x – 14 > 10x – 2 –4x > 12 x < –3
-
10 -8 -6 -4 -2 0 2 4 6 8 10
Practice Problems: 1. 2. 3. 4.
5 x − 1 > 14 7(2 x − 3) + 5 x = 19 − x 3 x + 42 ≥ 12 x − 12 5 − 4( x + 3) = 9
- A first degree equation has an equation of the form ax + by = c. To find the slope of a line, solve the equation for y. This gets the equation into slope intercept form:= y mx + b . The value m is the line's slope. - To find the y intercept, substitute 0 for x and solve for y. This is the y intercept. The y intercept is also the value of b in= y mx + b . - To find the x intercept, substitute 0 for y and solve for x . This is the x intercept. - If the equation solves to x = any number, then the graph is a vertical line. It only has an x intercept. Its slope is undefined. - If the equation solves to y = any number, then the graph is a horizontal line. It only has a y intercept. Its slope is 0 (zero).
MIDDLE LEVEL MATH.
76
TEACHER CERTIFICATION STUDY GUIDE 1. Find the slope and intercepts of 3 x + 2y = 14 .
3 x + 2y = 14 = 2y
−
3 x + 14
= y
−
3 2 x +7
The slope of the line is − 3 2 , the value of m. The y intercept of the line is 7. The intercepts can also be found by substituting 0 in place of the other variable in the equation. To find the y intercept: let x = 0; 3(0) + 2 y = 14 0 + 2 y = 14 2 y = 14 y=7 (0,7) is the y intercept.
To find the x intercept: let y = 0; 3 x + 2(0) = 14 3 x + 0 = 14 3 x = 14 x = 14 3 (14 3 ,0) is the x intercept.
Find the slope and the intercepts (if they exist) for these equations: 1. 5 x + 7 y = −70 2. x − 2y = 14 3. 5 x + 3 y = 3(5 + y ) 4. 2 x + 5 y = 15
-The absolute value function for a 1st degree equation is of the form: y= m( x − h) + k . Its graph is in the shape of a ∨ . The point (h,k) is the location of the maximum/minimum point on the graph. "± m" are the slopes of the 2 sides of the ∨ . The graph opens up if m is positive and down if m is negative.
MIDDLE LEVEL MATH.
77
TEACHER CERTIFICATION STUDY GUIDE
10 8 6 4 2 0 -10
-8
-6
-4
-2
-2
0
2
4
6
8
6
8
10
-4 -6 -8 -10
y = x + 3 +1 10 8 6 4 2 0 -10
-8
-6
-4
-2
0
2
4
-2 -4 -6 -8 -10
= y 2 x −3 10 8 6 4 2 -10
-8
-6
-4
-2
0 -2
0
2
4
6
-4 -6 -8 -10
= y −1 2 x − 4 − 3
MIDDLE LEVEL MATH.
78
8
10
10
TEACHER CERTIFICATION STUDY GUIDE -Note that on the first graph on the previous page, the graph opens up since m is positive 1. It has ( − 3,1) as its minimum point. The slopes of the 2 upward rays are ± 1. -The second graph also opens up since m is positive. Its minimum point is (0, -3). The slopes of the 2 upward rays are ± 2 . -The third graph is a downward ∧ because m is −1 2 . The maximum point on the graph is at (4, − 3) . The slopes of the 2 downward rays are ± 1 2 . -The identity function is the linear equation y = x . Its graph is a line going through the origin (0,0) and through the first and third quadrants at a 45° degree angle. 10 8 6 4 2 0 -10
-8
-6
-4
-2
0
2
4
6
8
10
-2 -4 -6 -8 -10
-The greatest integer function or step function has the equation: f(x )= j [rx − h] + k or y = j [rx − h] + k . (h,k) is the location of the left endpoint of one step. j is the vertical jump from step to step. r is the reciprocal of the length of each step. If ( x, y ) is a point of the function, then when x is an integer, its y value is the same integer. If ( x, y ) is a point of the function, then when x is not an integer, its y value is the first integer less than x . Points on
y = [ x ] would include:
(3,3), ( − 2, − 2), (0,0), (1.5,1), (2.83,2), ( − 3.2, − 4), ( −.4, −1).
MIDDLE LEVEL MATH.
79
TEACHER CERTIFICATION STUDY GUIDE
3 2 1 0 -4
-2
0
2
4
-1 -2 -3
y = [x] 5 4 3 2 1 -5
-4
-3
-2
0 -1-1 0
1
2
3
4
5
-2 -3 -4 -5
= y 2[ x ] − 3 -Note that in the graph of the first equation, the steps are going up as they move to the right. Each step is one space wide (inverse of r) with a solid dot on the left and a hollow dot on the right where the jump to the next step occurs. Each step is one square higher (j = 1) than the previous step. One step of the graph starts at (0,0) ← values of (h,k) . -In the second graph, the graph goes up to the right. One step starts at the point (0,− 3) ← values of (h,k). Each step is one square wide (r = 1) and each step is 2 squares higher than the previous step ( j = 2) .
MIDDLE LEVEL MATH.
80
TEACHER CERTIFICATION STUDY GUIDE Practice: Graph the following equations: 1. f(x ) = x − x −3 +5 2. y = 3. y = 3 [ x ] 4. = y 2 5 x −5 −2 A rational function is given in the form f ( x ) = p( x ) q( x ) . In the equation, p( x ) and q( x ) both represent polynomial functions where q( x ) does not equal zero. The branches of rational functions approach asymptotes. Setting the denominator equal to zero and solving will give the value(s) of the vertical asymptotes(s) since the function will be undefined at this point. If the value of f( x ) approaches b as the x increases, the equation y = b is a horizontal asymptote. To find the horizontal asymptote it is necessary to make a table of values for x that are to the right and left of the vertical asymptotes. The pattern for the horizontal asymptotes will become apparent as the x increases. If there is more than one vertical asymptote, remember to choose numbers to the right and left of each one in order to find the horizontal asymptotes and have sufficient points to graph the function.
MIDDLE LEVEL MATH.
81
TEACHER CERTIFICATION STUDY GUIDE Sample problem: 1. Graph f( x ) =
3x + 1 . x −2
1. Set denominator = 0 to find the vertical asymptote.
x −2 = 0 x=2
x 3 10 100 1000 1
3. The pattern shows that as x increases, f( x ) approaches
10 100
2.417 2.93
the value 3; therefore a horizontal asymptote exists at y = 3
1000
2.99
− − −
2. Make a table, choosing numbers to the right and left of the vertical asymptote.
f( x ) 10 3.875 3.07 3.007 − 4
Sketch the graph. 10
8
6
4
2
-20
-15
-10
-5
0
0
5
10
-2
-4
-6
MIDDLE LEVEL MATH.
82
15
20
TEACHER CERTIFICATION STUDY GUIDE Functions defined by two or more formulas are piecewise functions. The formula used to evaluate piecewise functions varies depending on the value of x. The graphs of piecewise functions consist of two or more pieces, or intervals, and are often discontinuous. Example 1:
Example 2:
f(x) = x + 1 if x > 2 x – 2 if x < 2
5
f(x) = x if x > 1 x2 if x < 1
f(x)
5
x
x -5
f(x)
-5
5
5
-5
-5
When graphing or interpreting the graph of piecewise functions, it is important to note the points at the beginning and end of each interval; because the graph must clearly indicate what happens at the end of each interval. Note that in the graph of Example 1, point (2, 3) is not part of the graph and is represented by an empty circle. On the other hand, point (2, 0) is part of the graph and is represented as a solid circle. Note also that the graph of Example 2 is continuous despite representing a piecewise function. Practice: Graph the following piecewise equations. 1. f(x) = x2 =x+4
if x > 0 if x < 0
2. f(x) = x2 – 1 = x2 + 2
if x > 2 if x < 2
MIDDLE LEVEL MATH.
83
TEACHER CERTIFICATION STUDY GUIDE Competency 0012
Understand properties and applications of linear, quadratic, exponential, and trigonometric functions and solve related equations and inequalities.
A first degree equation can be written in the form ax + by = c. To graph this equation, find either one point and the slope of the line, or find two points. To find a point and slope, solve the equation for y. This gets the equation in the slope-intercept form, y = mx + b. The point (0,b) is the y-intercept and m is the line's slope. To find two points, substitute any number for x, then solve for y. Repeat this with a different number. To find the intercepts, substitute 0 for x and then 0 for y. Remember that graphs will go up as they go to the right when the slope is positive. Negative slopes make the lines go down as they go to the right. If the equation solves to x = a constant, then the graph is a vertical line. It only has an x- intercept. Its slope is undefined. If the equation solves to y = a constant, then the graph is a horizontal line. It only has a y-intercept. Its slope is 0 (zero). When graphing a linear inequality, the line will be dotted if the inequality sign is < or >. If the inequality signs are either ≤ or ≥ , the line on the graph will be a solid line. Shade above the line when the inequality sign is > or ≥ . Shade below the line when the inequality sign is < or ≤ . For inequalities of the form x > k, x ≥ k , x< k, or x ≤ k where k = any number, the graph will be a vertical line (solid or dotted.) Shade to the right for > or ≥ . Shade to the left for < or ≤ . Remember: Dividing or multiplying by a negative number will reverse the direction of the inequality sign.
MIDDLE LEVEL MATH.
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TEACHER CERTIFICATION STUDY GUIDE Examples:
3x + 12 > -3 x > -5
3x - 2y ≥ 6 y ≤ 23 x - 3
5x + 2y = 6 y = - 25 x+ 3
Word problems can sometimes be solved by using a system of two equations in 2 unknowns. This system can then be solved using substitution, or the addition-subtraction method. Example: Farmer Greenjeans bought 4 cows and 6 sheep for $1700. Mr. Ziffel bought 3 cows and 12 sheep for $2400. If all the cows were the same price and all the sheep were another price, find the price charged for a cow or for a sheep. Let x = price of a cow Let y = price of a sheep Then Farmer Greenjeans' equation would be: 4 x + 6 y = 1700 Mr. Ziffel's equation would be: 3 x + 12y = 2400 To solve by addition-subtraction: Multiply the first equation by −2 : −2(4 x + 6 y = 1700) Keep the other equation the same: (3 x + 12y = 2400) By doing this, the equations can be added to each other to eliminate one variable and solve for the other variable. −8 x − 12y = −3400 3 x + 12y = 2400 −5 x
Add these equations.
= −1000
= x 200 ← the price of a cow was $200.
MIDDLE LEVEL MATH.
85
TEACHER CERTIFICATION STUDY GUIDE Solving for y ,= y 150 ← the price of a sheep was $150. To solve by substitution: Solve one of the equations for a variable. (Try to make an equation without fractions if possible.) Substitute this expression into the equation that you have not yet used. Solve the resulting equation for the value of the remaining variable. 4 x + 6y = 1700 3 x + 12y = 2400 ← Solve this equation for x .
It becomes= x 800 − 4 y . Now substitute 800 − 4y in place of x in the OTHER equation. 4 x + 6 y = 1700 now becomes: 4(800 − 4 y ) + 6 y = 1700 3200 − 16 y + 6 y = 1700 3200 − 10 y = 1700 −10 y = −1500 y = 150 , or $150 for a sheep.
Substituting 150 back into an equation for y , find x . 4 x + 6(150) = 1700 4 x + 900 = 1700 4 x = 800 so x = 200 for a cow. Word problems can sometimes be solved by using a system of three equations in 3 unknowns. This system can then be solved using substitution or the addition-subtraction method.
MIDDLE LEVEL MATH.
86
TEACHER CERTIFICATION STUDY GUIDE To solve by substitution: Example: Mrs. Allison bought 1 pound of potato chips, a 2-pound beef roast, and 3 pounds of apples for a total of $8.19. Mr. Bromberg bought a 3-pound beef roast and 2 pounds of apples for $9.05. Kathleen Kaufman bought 2 pounds of potato chips, a 3pound beef roast, and 5 pounds of apples for $13.25. Find the per pound price of each item. Let x = price of a pound of potato chips Let y = price of a pound of roast beef Let z = price of a pound of apples Mrs. Allison's equation would be: 1x + 2y + 3z = 8.19 Mr. Bromberg's equation would be: 3 y + 2z = 9.05 K. Kaufman's equation would be: 2 x + 3 y + 5z = 13.25 Take the first equation and solve it for x . (This was chosen because x is the easiest variable to get alone in this set of equations.) This equation would become: x = 8.19 − 2y − 3z
Substitute this expression into the other equations in place of the letter x : 3 y + 2z= 9.05 ← equation 2 2(8.19 − 2y − 3z ) + 3 y + 5= z 13.25 ← equation 3
Simplify the equation by combining like terms: 3 y + 2z= 9.05 ← equation 2 * −1y − 1z = −3.13 ← equation 3
Solve equation 3 for either y or z : = y 3.13 − z
Substitute this into equation 2 for y :
3(3.13 − z ) + 2z= 9.05 ← equation 2 −1y − 1z = −3.13 ← equation 3
MIDDLE LEVEL MATH.
87
TEACHER CERTIFICATION STUDY GUIDE Combine like terms in equation 2: 9.39 − 3z + 2z = 9.05 z = .34 per pound price of apples
Substitute .34 for z in the starred equation above to solve for y : y = 3.13 −z becomes = y 3.13 − .34 , so y = 2.79 = per pound price of roast beef Substituting .34 for z and 2.79 for y in one of the original equations, solve for x : 1x + 2y + 3z = 8.19 1x + 2(2.79) + 3(.34) = 8.19 x + 5.58 + 1.02 = 8.19 x + 6.60 = 8.19 x = 1.59 per pound of potato chips ( x, y , z ) = (1.59, 2.79, .34)
To solve by addition-subtraction: Choose a letter to eliminate. Since the second equation is already missing an x , eliminate x from equations 1 and 3. 1) 2) 3)
1x + 2y + 3 x= 8.19 ← Multiply by −2 below. 3 y + 2z = 9.05 2 x + 3 y + 5z = 13.25
−2(1x + 2y + 3z = 8.19) = −2 x − 4 y − 6z = −16.38 Keep equation 3 the same : 2 x + 3 y + 5z = 13.25 By doing this, the equations can be added to each other to eliminate one variable. − y − z =−3.13 ← equation 4
The equations left to solve are equations 2 and 4: − y − z =−3.13 ← equation 4 3 y + 2z= 9.05 ← equation 2
MIDDLE LEVEL MATH.
88
TEACHER CERTIFICATION STUDY GUIDE Multiply equation 4 by 3: 3( − y − z =−3.13) Keep equation 2 the same: 3 y + 2z = 9.05 −3 y − 3z = −9.39 3 y + 2z = 9.05
Add these equations.
− 1z = −.34 = z .34 ← the per pound price of apples solving for y= , y 2.79 ← the per pound roast beef price , x 1.59 ← potato chips, per pound price solving for x= Example: Sharon's Bike Shoppe can assemble a 3 speed bike in 30 minutes or a 10 speed bike in 60 minutes. The profit on each bike sold is $60 for a 3 speed or $75 for a 10 speed bike. How many of each type of bike should they assemble during an 8 hour day (480 minutes) to make the maximum profit? Total daily profit must be at least $300. Let x = number of 3 speed bikes. y = number of 10 speed bikes. Since there are only 480 minutes to use each day, 30 x + 60 y ≤ 480 is the first inequality.
Since the total daily profit must be at least $300, 60 x + 75 y ≥ 300 is the second inequality. 30 x + 60 y ≤ 480 solves to y ≤ 8 − 1 2 x 60y ≤ -30x + 480
1 y ≤ − x +8 2 60 x + 75 y ≥ 300 solves to y ≥ 4 − 4 5 x 75y + 60x ≥ 300
75y ≥ −60x + 300 4 y ≥ − x+4 5
MIDDLE LEVEL MATH.
89
TEACHER CERTIFICATION STUDY GUIDE Graph these 2 inequalities: y ≤ 8 −1 2 x y ≥ 4− 4 5x Daily Production of Bikes Sold
9
Number of 10 Speed Bikes Sold
8 7
y ≤8−
6
1 x 2
5 4 3 2
y ≥ 4−
1
4 x 5
0 0
5
10
15
20
Number of 3 Speed Bikes Sold
Realize that x ≥ 0 and y ≥ 0 , since the number of bikes assembled can not be a negative number. Graph these as additional constraints on the problem. The number of bikes assembled must always be an integer value, so points within the shaded area of the graph must have integer values. The maximum profit will occur at or near a corner of the shaded portion of this graph. Those points occur at (0,4), (0,8), (16,0), or (5,0). Since profits are $60 3 -speed or $75 10 -speed, the profit would be : (0,4) (0,8) (16,0) (5,0)
60(0) + 75(4) = 300 60(0) + 75(8) = 600 60(16) + 75(0) =960 ← Maximum profit 60(5) + 75(0) = 300
The maximum profit would occur if 16 3-speed bikes are made daily.
MIDDLE LEVEL MATH.
90
TEACHER CERTIFICATION STUDY GUIDE The discriminant of a quadratic equation is the part of the quadratic formula that is usually inside the radical sign, b 2 − 4ac . x=
−b ± b2 − 4ac 2a
The radical sign is NOT part of the discriminant!! Determine the value of the discriminant by substituting the values of a , b , and c from ax 2 + bx + c = 0. -If the value of the discriminant is any negative number, then there are two complex roots including "i.” -If the value of the discriminant is zero, then there is only 1 real rational root. This would be a double root. -If the value of the discriminant is any positive number that is also a perfect square, then there are two real rational roots. (There are no longer any radical signs.) -If the value of the discriminant is any positive number that is NOT a perfect square, then there are two real irrational roots. (There are still unsimplified radical signs.) Example: Find the value of the discriminant for the following equations. Then determine the number and nature of the solutions of that quadratic equation. 2x 2 − 5x + 6 = 0 A) a = 2, b = − 5, c = 6 so b2 − 4ac = ( − 5)2 − 4(2)(6) = 25 − 48 = − 23 .
Since − 23 is a negative number, there are two complex roots including "i". 5 i 23 x= + , 4 4
B)
5 i 23 x= − 4 4
3 x 2 − 12 x + 12 = 0
a = 3, b = −12, c = 12 so b2 − 4ac = ( −12)2 − 4(3)(12) = 144 − 144 = 0
Since 0 is the value of the discriminant, there is only 1 real rational root. x=2
MIDDLE LEVEL MATH.
91
TEACHER CERTIFICATION STUDY GUIDE
C)
6x 2 − x − 2 = 0
a= 6, b =−1, c =− 2 so b2 − 4ac = ( −1)2 − 4(6)( − 2) =+ 1 48 = 49 .
Since 49 is positive and is also a perfect square ( 49 ) = 7 , then there are two real rational roots. x=
2 1 , x= − 3 2
Try these: 1. 6 x 2 − 7 x − 8 = 0 2. 10 x 2 − x − 2 = 0 3. 25 x 2 − 80 x + 64 = 0
A quadratic equation is written in the form ax 2 + bx + c = 0 . To solve a quadratic equation by factoring, at least one of the factors must equal zero. Example: Solve the equation. x 2 + 10 x − 24 = 0 ( x + 12)( x − 2) = 0 x += 12 0 or x − = 2 0 = x −= 12 x 2
Factor. Set each factor equal to 0. Solve.
Check: x 2 + 10 x − 24 = 0 ( −12)2 + 10( −12)= − 24 0 (2)2 + 10(2)= − 24 0 144 −= 120 − 24 0 4= + 20 − 24 0 = 0 0= 0 0
MIDDLE LEVEL MATH.
92
TEACHER CERTIFICATION STUDY GUIDE A quadratic equation that cannot be solved by factoring can be solved by completing the square. Example: Solve the equation. x 2 − 6x + 8 = 0 −8 x 2 − 6x =
Move the constant to the right side.
x 2 − 6x + 9 = − 8 + 9
Add the square of half the coefficient of x to both sides.
( x − 3)2 = 1
Write the left side as a perfect square.
x − 3 =± 1
Take the square root of both sides.
x= −3 1 x= − 3 −1 x 4= x 2 =
Solve.
Check: x 2 − 6x + 8 = 0 = 42 − 6(4) + 8 0 = 22 − 6(2) + 8 0 = 16 − 24 + 8 0 = 4 − 12 + 8 0 = 0 0= 0 0
To solve a quadratic equation using the quadratic formula, be sure 2 0 . Substitute these that your equation is in the form ax + bx + c = values into the formula: −b ± b2 − 4ac x= 2a
MIDDLE LEVEL MATH.
93
TEACHER CERTIFICATION STUDY GUIDE Example: 2 Graph y= 3 x + x − 2 .
x −2 −1 0 1 2
y= 3 x 2 + x − 2 8 0 −2 2 12
10 8 6 4 2 0 -10
-8
-6
-4
-2
0
2
4
-2 -4 -6 -8 -10
MIDDLE LEVEL MATH.
94
6
8
10
TEACHER CERTIFICATION STUDY GUIDE To solve a quadratic equation using the quadratic formula, be sure 2 0 . Substitute these that your equation is in the form ax + bx + c = values into the formula:
x=
−b ± b2 − 4ac 2a
Example: Solve the equation. 3 x 2 = 7 + 2x → 3 x 2 − 2x − 7 = 0 a= 3 b= −2 c = −7 −( −2) ± ( −2)2 − 4(3)( −7) x= 2(3) x=
2 ± 4 + 84 6
x=
2 ± 88 6
x=
2 ± 2 22 6
x=
1 ± 22 3
MIDDLE LEVEL MATH.
95
TEACHER CERTIFICATION STUDY GUIDE To solve a quadratic equation (with x 2 ), rewrite the equation into the form: ax 2 + bx + c = 0 or y = ax 2 + bx + c
where a , b , and c are real numbers. Then substitute the values of a , b , and c into the quadratic formula: −b ± b2 − 4ac x= 2a
Simplify the result to find the answers. (Remember, there could be 2 real answers, one real answer, or 2 complex answers that include "i"). To solve a quadratic inequality (with x 2 ), solve for y . The axis of symmetry is located at x = −b 2a . Find coordinates of points to each side of the axis of symmetry. Graph the parabola as a dotted line if the inequality sign is either < or > . Graph the parabola as a solid line if the inequality sign is either ≤ or ≥ . Shade above the parabola if the sign is ≥ or > . Shade below the parabola if the sign is ≤ or < . Example: Solve: 8 x 2 − 10 x − 3 = 0 In this equation a = 8 , b = −10 , and c = −3 . Substituting these into the quadratic equation, it becomes: = x = x
−( −10) ± ( −10)2 − 4(8)( −3) 10 ± 100 + 96 = 2(8) 16 10 ± 196 10 ± 14 24 −4 3 1 = = or = or − 16 16 16 16 2 4
Check: x= −
1 4
1 10 + −3 = 0 2 4 3−3 = 0
MIDDLE LEVEL MATH.
Both Check
96
TEACHER CERTIFICATION STUDY GUIDE Example: Solve and graph: y > x 2 + 4 x − 5 . The axis of symmetry is located at x = −b 2a . Substituting 4 for b , and 1 for a , this formula becomes: = x − (4) = 2(1) −= 4 2 −2 Find coordinates of points to each side of x = − 2 . x
y
−5
0
−4
−5
dotted line. Since a greater than sign is used, shade
−3
−8
above and inside the parabola.
−
−
−
2
9
−
1
−
0 1
Graph these points to form a parabola. Draw it as a
8
5 0 10 8 6 4 2 0
-10
-8
-6
-4
-2
0 -2 -4 -6 -8 -10
MIDDLE LEVEL MATH.
97
2
4
6
8
10
TEACHER CERTIFICATION STUDY GUIDE There are 2 easy ways to find the values of a function. First, to find the value of a function when x = 3 , substitute 3 in place of every letter x . Then simplify the expression following the order of operations. For example, if f( x ) = x 3 − 6 x + 4 , then to find f(3), substitute 3 for x . The equation becomes f(3) = 33 − 6(3) + 4 = 27 − 18 + 4 = 13. So (3, 13) is a point on the graph of f(x). A second way to find the value of a function is to use synthetic division. To find the value of a function when x = 3 , divide 3 into the coefficients of the function. (Remember that coefficients of missing terms, like x 2 , must be included). The remainder is the value of the function. If f( x ) = x 3 − 6 x + 4 , then to find f(3) using synthetic division: Note the 0 for the missing x2 term.
3
−
1 0 3
6 4 9 9 3 13 ← this is the value of the function.
1 3
Therefore, (3, 13) is a point on the graph of f(x) = x 3 − 6 x + 4 . Example: Find values of the function at integer values from x = -3 to x = 3 if f( x ) = x 3 − 6 x + 4 . If x = − 3 : f( − 3) = ( − 3)3 − 6( − 3) + 4 = ( − 27) − 6( − 3) + 4 −
=
27 + 18 + 4=
−
5
Synthetic division: −
3
1 0 −
3
−
6 4 9
−
9
− 1 − 3 3 − 5 ← this is the value of the function if x = 3. − − Therefore, ( 3, 5 ) is a point on the graph.
MIDDLE LEVEL MATH.
98
TEACHER CERTIFICATION STUDY GUIDE If x = − 2 : f( − 2) = ( − 2)3 − 6( − 2) + 4 =( − 8) − 6( − 2) + 4 = − 8 + 12 + 4 = 8 ← this is the value of the function if x = − 2. Therefore, ( − 2 , 8) is a point on the graph.
If x = −1 : f( −1) = ( −1)3 − 6( −1) + 4 =( −1) − 6( −1) + 4 =
−
1+ 6 + 4 = 9
Synthetic division: −
1
−
1 0 −
1
6 4 1 5
− 1 −1 − 5 9 ← this is the value if the function if x = 1. − Therefore, ( 1 , 9) is a point on the graph.
If x = 0 :
f(0) = (0)3 − 6(0) + 4 =− 0 6(0) + 4 = 0 − 0 + 4 = 4 ← this is the value of the function if x = 0. Therefore, ( 0, 4) is a point on the graph. If x = 1 : f(1) = (1)3 − 6(1) + 4 =(1) − 6(1) + 4 =1 − 6 + 4 = − 1
Synthetic division: 1
1 0 1
−
6 4
1
−
5
1 1 − 5 −1 ← this is the value if the function of x = 1. − Therefore, ( 1, 1 ) is a point on the graph. MIDDLE LEVEL MATH.
99
TEACHER CERTIFICATION STUDY GUIDE If x = 2 :
f(2) = (2)3 − 6(2) + 4 =− 8 6(2) + 4 = 8 − 12 + 4 = 0 Synthetic division: 2
1 0 2
−
6 4
4
−
4
1 2 − 2 0 ← this is the value of the function if x = 2. Therefore, ( 2, 0) is a point on the graph. If x = 3 :
f(3) = (3)3 − 6(3) + 4 =27 − 6(3) + 4 = 27 − 18 + 4 = 13 Synthetic division:
3
1 0 3
−
6 4 9 9
1 3 3 13 ← this is the value of the function if x = 3. Therefore, ( 3, 13) is a point on the graph.
MIDDLE LEVEL MATH.
100
TEACHER CERTIFICATION STUDY GUIDE The following points are points on the graph: X
Y
−
−
3 − 2 − 1 0 1 2 3
Note the change in sign of the y value between x = − 3 and x = − 2 . This indicates there is a zero between x = − 3 and x = − 2 . Since there is another change in sign of the y value between x = 0 and x = −1 , there is a second root there. When x = 2 , y = 0 so x = 2 is an exact root of this polynomial.
5 8 9 4 − 1 0 13
10 8 6 4 2 0 -10
-8
-6
-4
-2
0
2
4
6
8
10
-2 -4 -6 -8 -10
A local maximum or a local minimum is a point where the graph changes direction. These points are called turning points. • At a local maximum the function changes from an increasing function to a decreasing function • At a local minimum the function changes from a decreasing function to an increasing function If f is a polynomial function of degree n, then f has at most n – 1 turning points.
MIDDLE LEVEL MATH.
101
TEACHER CERTIFICATION STUDY GUIDE Definition: A function f is even (symmetric about the y-axis) if f ( − x ) = f( x ) and odd (symmetric about the origin) if f ( − x ) = − f( x ) for all x in the domain of f. Sample problems: Determine if the given function is even, odd, or neither even nor odd. 1. Find f ( − x ) .
1. f( x ) =x 4 − 2 x 2 + 7 f( − x ) =( − x )4 − 2( − x )2 + 7
2. Replace x with − x .
f( − x ) =x 4 − 2 x 2 + 7
3. Since f ( − x ) = f( x ) , f(x) is an even function. 1. Find f ( − x ) .
2. f (= x ) 3 x 3 + 2x = f( − x ) 3( − x )3 + 2( − x ) − f(= x)
−
3 x 3 − 2x
3. Since f ( x ) is not equal to f ( − x ) , f(x) is not an even function. 4. Try − f( x ) .
− = f( x )
−
(3 x 3 + 2 x )
−
−
3 x 3 − 2x
= f( x )
2. Replace x with − x .
5. Since f ( − x ) = − f( x ) , f(x) is an odd function. 1. First find g ( − x ) .
3. g ( x = ) 2x 2 − x + 4 g ( − x )= 2( − x )2 − ( − x ) + 4
2. Replace x with − x .
g ( − x )= 2 x 2 + x + 4
3. Since g ( x ) does not equal
−
g(= x)
−
(2 x 2 − x + 4)
g ( − x ) , g(x) is not an even function. 4. Try − g( x ) .
−
g( = x)
−
2x 2 + x − 4
5. Since − g( x ) does not equal g ( − x ) , g ( x ) is not an odd function. g ( x ) is neither even nor odd.
MIDDLE LEVEL MATH.
102
TEACHER CERTIFICATION STUDY GUIDE Synthetic division can be used to find the value of a function at any value of x . To do this, divide the value of x into the coefficients of the function. (Remember that coefficients of missing terms, like x 2 below, must be included.) The remainder of the synthetic division is the value of the function. If f( x ) = x 3 − 6 x + 4 , then to find the value of the function at x = 3 , use synthetic division: Note the 0 for the missing x 2 term. 3
1
0 3
1
3
−
6 9
4 9
3 13 ← This is the value of the function.
Therefore, ( 3, 13) is a point on the graph. Example: Find values of the function at x = − 5 if f( x ) = 2 x 5 − 4 x 3 + 3 x 2 − 9 x + 10 . Note the 0 below for the missing x 4 term. Synthetic division: − 2
5
0 −
−
4
3
−
9
10
10 50 − 230 1135 − 5630
− 5. 2 −10 46 − 227 1126 − 5620 ← This is the value of the function if x =
Therefore, ( − 5 , − 5620 ) is a point on the graph. Note that if x = − 5 , the same value of the function can also be found by substituting − 5 in place of x in the function. f( − 5) = 2( − 5)5 − 4( − 5)3 + 3( − 5)2 − 9( − 5) + 10 = 2( − 3125) − 4( −125) + 3(25) − 9( − 5) + 10 =
−
6250 + 500 + 75 + 45 + 10 =
−
5620
Therefore, ( − 5 , − 5620 ) is still a point on the graph.
MIDDLE LEVEL MATH.
103
TEACHER CERTIFICATION STUDY GUIDE To determine if ( x − a ) or ( x + a ) is a factor of a polynomial, do a synthetic division, dividing by the opposite of the number inside the parentheses. To see if ( x − 5 ) is a factor of a polynomial, divide it by 5. If the remainder of the synthetic division is zero, then the binomial is a factor of the polynomial. If f( x ) = x 3 − 6 x + 4 , determine if ( x − 1) is a factor of f( x ) . Use synthetic division and divide by 1: Note the 0 for the missing x 2 term.
1
1
0 1
−
6
4
1 −5
1 1 −5
−1 ← This is the remainder of the function.
Therefore, ( x − 1) is not a factor of f( x ). If f( x ) = x 3 − 6 x + 4 , determine if ( x − 2 ) is a factor of f( x ). Use synthetic division and divide by 2:
2
1
0 2
−
6
4
4 −4
2 −2
1
0 ← This is the remainder of the function.
Therefore, ( x − 2 ) is a factor of f( x ). The converse of this is also true. If you divide by k in any synthetic division and get a remainder of zero for the division, then ( x − k ) is
a factor of the polynomial. Similarly, if you divide by −k in any synthetic division and get a remainder of zero for the division, then ( x + k ) is a factor of the polynomial. Divide 2 x 3 − 6 x − 104 by 4. What is your conclusion? 4
2 2
0 8 8
−6
−104
32
104
26
0 ← This is the remainder of the function.
Since the remainder is 0, then ( x − 4 ) is a factor.
MIDDLE LEVEL MATH.
104
TEACHER CERTIFICATION STUDY GUIDE Given any polynomial, be sure that the exponents of the terms are in descending order. List out all the factors of the first term's coefficient, and of the constant in the last term. Make a list of fractions by putting each of the factors of the last term's coefficient over each of the factors of the first term. Reduce fractions when possible. Put a ± in front of each fraction. This list of fractions is a list of the only possible rational roots of a function. If the polynomial is of degree n, then at most n of these will actually be roots of the polynomial. Example: List the possible rational roots for the function f( x ) = x 2 − 5 x + 4 . ± factors of 4 = factors of 1
± 1, 2, 4 ← 6 possible rational roots
Example: List the possible rational roots for the function f( x ) = 6 x 2 − 5 x − 4 . Make fractions of the form : possible
factors of 4 1,2,4 rational roots = ± = ± = factors of 6 1,2,3,6 1 1 1 2 4 ± , , , , ,1,2,4 are the only 16 rational 2 3 6 3 3 numbers that could be roots. Since this equation is of degree 2, there are, at most, 2 rational roots. (They happen to be 4 3 and −1 2 .) Descarte's Rule of signs can help to determine how many positive real roots or how many negative real roots a function would have. Given any polynomial, be sure that the exponents of the terms are in descending order. Count the number of successive terms of the polynomial where there is a sign change. The number of positive roots will be equal to the number of sign changes or will be less than the number of sign changes by a multiple of 2. For example,
y = 2 x 5 + 3 x 4 − 6 x 3 + 4 x 2 + 8 x − 9 has 3 sign →1 → 2 → 3 ch anges. That means that this equation will have either 3 positive roots or 1 positive root. MIDDLE LEVEL MATH.
105
TEACHER CERTIFICATION STUDY GUIDE The equation:
y = 4 x 6 − 5 x 5 + 6 x 4 − 3 x 3 + 2 x 2 + 8 x − 10 →1 → 2 → 3 → 4 →5
has 5 sign changes.
This equation will have either 5 positive roots (equal to the number of sign changes) or 3 positive roots (2 less) or only 1 positive root (4 less). The equation:
y =x 8 − 3 x 5 − 6 x 4 − 3 x 3 + 2 x 2 − 8 x + 10 →1 →2 →3 →4
has 4 sign changes.
This equation will have either 4 positive roots (equal to the number of sign changes) or 2 positive roots (2 less) or no positive roots( 4 less). The second part of Descarte's Rule of signs also requires that terms are in descending order of exponents. Next, look at the equation and change the signs of the terms that have an odd exponent. Then count the number of sign changes in successive terms of the new polynomial. The number of negative terms will be equal to the number of sign changes, or will be less than the number of sign changes by a multiple of 2. For example, given the equation: y = 2x 5 + 3 x 4 − 6 x 3 + 4 x 2 + 8 x − 9
Change the signs of the terms with odd exponents. y= −2 x 5 + 3 x 4 + 6 x 3 + 4 x 2 − 8 x − 9 Now count the number of sign changes in this equation. y= −2 x 5 + 3 x 4 + 6 x 3 + 4 x 2 − 8 x − 9 →1 →2
has 2 sign changes.
This tells you that there are 2 negative roots or 0 negative roots (2 less).
MIDDLE LEVEL MATH.
106
TEACHER CERTIFICATION STUDY GUIDE Example: Determine the number of positive or negative real roots for the equation: y =x 3 + 9 x 2 + 23 x + 15
This equation is of degree 3, so it has, at most, 3 roots. Look at the equation. There are 0 sign changes. This means there are 0 positive roots. To check for negative roots, change the signs of the terms with odd exponents. The equation becomes:
y= − x 3 + 9 x 2 − 23 x + 15 →1 → 2 → 3
Now count sign changes. There are 3 sign changes.
This means there are either 3 negative roots or only 1 negative root. To find points on the graph of a polynomial, substitute desired values in place of x and solve for the corresponding y value of that point on the graph. A second way to do the same thing is to do a synthetic division, dividing by the x value of the desired point. The remainder at the end of the synthetic division is the y value of the point. Find a group of points to plot, then graph and connect the points from left to right on the graph. The y intercept will always have a y value equal to the constant of the equation.
MIDDLE LEVEL MATH.
107
TEACHER CERTIFICATION STUDY GUIDE Exercise: For 2000 through 2005, the consumption of a certain product sweetened with sugar, as a percent, f (t ) , of the total consumption of the product, can be modeled by: f (t= ) 75 + 37.25(0.615)t where t = 2 represents 2000. (a)
Find a model for the consumption of the product sweetened with non-sugar sweeteners as a percent, g (t ) , of the total consumption of the product. Since 100% represents the total consumption of the product, the model can be found by subtracting the model for sugarsweetened product from 100: g (t ) = 100 − (75 + 37.25(0.615)t = 100 − 75 − 37.25(0.615)t = 25 − 37.25(0.615)t
(b)
Sketch the graphs of f and g . Does the consumption of one type of product seem to be stabilizing compared to the other product? Explain. 120
100 f(t) 80
60
40 g(t)
20
1
MIDDLE LEVEL MATH.
2
108
3
4
5
6
TEACHER CERTIFICATION STUDY GUIDE Yes, the consumption of the product sweetened with sugar (represented by f (t ) ) is decreasing less and less each year. (c)
Sketch the graph of f ( x) = 2 x . Does it have an x-intercept ? What does this tell you about the number of solutions of the equation 2 x = 0 ? Explain. f(x)
4
3
2
1
-3
-2
-1
1
2
3
No, there is no solution. The solutions of 2 x = 0 are the xintercepts of y = 2 x .
MIDDLE LEVEL MATH.
109
TEACHER CERTIFICATION STUDY GUIDE Unlike trigonometric identities that are true for all values of the defined variable, trigonometric equations are true for some, but not all, of the values of the variable. Most often trigonometric equations are solved for values between 0 and 360 degrees or 0 and 2 π radians. Some algebraic operations, such as squaring both sides of an equation, will give you extraneous answers. You must remember to check all solutions to be sure that they work. Sample problems: 1. Solve: cos x =1 − sin x if 0 ≤ x < 360 degrees. 1. square both sides cos2 x= (1 − sin x )2
1 − sin2 x = 1 − 2sin x + sin2 x = 0 − 2sin x + 2sin2 x = 0 2 sin x ( −1 + sin x )
2. substitute 3. set = to 0 4. factor
− 2sin = x 0 1 + sin = x 0 5. set each factor = 0 6. solve for sin x = sin x 0= sin x 1 7. find value of sin at x = x 0= or 180 x 90
The solutions appear to be 0, 90 and 180. Remember to check each solution and you will find that 180 does not give you a true equation. Therefore, the only solutions are 0 and 90 degrees. 2. Solve:= cos2 x sin2 x if 0 ≤ x < 2π 1. cos2 x = 1 − cos2 x 2 2. 2cos x = 1 1 3. cos2 x = 2 1 cos2 x = ± 4. 2 ± 2 2 π 3π 5π 7π x= , , , 4 4 4 4
cos x =
MIDDLE LEVEL MATH.
110
substitute simplify divide by 2 take square root
5. rationalize denominator
TEACHER CERTIFICATION STUDY GUIDE Answer Key to Practice Problems
Competency 1, page 7 Question #1 Question #2 Question #3 Question #4
The Red Sox won the World Series. Angle B is not between 0 and 90 degrees. Annie will do well in college. You are witty and charming.
Competency 11, page 72 Question #2 Question #3 Question #4 Question #5 Question #6
a, b, c, f are functions Domain = − ∞, ∞ Range = − 5, ∞ Domain = −∞, ∞ Range = −6, ∞ Domain = 1,4,7,6 Range = -2 Domain = x ≠ 2,− 2
Question #7 Domain = − ∞, ∞ −
Domain = ∞, ∞
Range = -4, 4 Range = 2, ∞
−
Question #8 Domain = ∞, ∞ Range = 5 Question #9 (3, 9), (-4,16), (6, 3), (1, 9), (1, 3)
page 76 5 7 1 slope = 2
Question #1 x-intercept = -14
y-intercept = -10 slope = −
Question #2 x-intercept = 14
y-intercept = -7
Question #3 x-intercept = 3 15 Question #4 x-intercept = 2
y-intercept = none
MIDDLE LEVEL MATH.
y-intercept = 3
111
slope = −
2 5
TEACHER CERTIFICATION STUDY GUIDE page 77 Question #1 x>3
0 Question #2 x=2
0 Question #3 x<6
0 Question #4 x = -4
0
MIDDLE LEVEL MATH.
112
TEACHER CERTIFICATION STUDY GUIDE page 81 Question #1
Question #2 4
6
3
5
2
4
1
3
0 -5
-1 0
2
5
1
-2
0 -3 -2 -1 0 1 2 3 4 5 6 7 8 9
-3 -4
Question #3
Questions #4 6 5 4 3 2 1 0 -1 0 1 2 3 4 5 6 7 8 9 10 11 12 -2 -3 -4
5 4 3 2 1 0 -2
-1
-1
0
1
2
page 83 Question #1
Question #2 8 6 4
0,4
2,4
2 0 -6
-4
-2
-2 0
2
4
6
-4 -6 -8
-8
-6
-4
8 6 2,6 4 2 0 0,2 -2 -2 0 2 -4 -6 -8
Competency 12, page 92 Question #1 discriminant = 241; 2 real irrational roots Question #2 discriminant = 81; 2 real rational roots Question #3 discriminant = 0; 1 real rational root
MIDDLE LEVEL MATH.
113
3,8 2,3 4
6
8
TEACHER CERTIFICATION STUDY GUIDE Sample Test 1) Given
W = whole numbers N = natural numbers Z = integers R = rational numbers I = irrational numbers
4) Choose the correct statement: A) Rational and irrational numbers are both proper subsets of the real numbers.
Which of the following is not true? A) R ⊂ I
B) The set of whole numbers is a proper subset of the set of natural numbers.
B) W ⊂ Z
C) The set of integers is a proper subset of the set of irrational numbers.
C) Z ⊂ R D) N ⊂ W
D) The set of real numbers is a proper subset of the natural, whole, integers, rational, and irrational numbers.
2) Which of the following is an irrational number? A) .362626262...
5) Which statement is an example of the identity axiom of addition?
B) 4 13 C)
5 A) 3 + -3 = 0
D) - 16
B) 3x = 3x + 0
3) Which denotes a complex number?
C) 3 ⋅
B) - 16 127
D)
−100
MIDDLE LEVEL MATH.
=1
D) 3 + 2x = 2x + 3
A) 4.1212121212...
C)
1 3
114
TEACHER CERTIFICATION STUDY GUIDE 8) How many real numbers lie between -1 and +l ?
6) Which axiom is incorrectly applied?
A) 0
3x + 4 = 7
B) 1 Step a 3x + 4 - 4 = 7 - 4 C) 17 additive equality D) an infinite number Step b 3x + 4 - 4 = 3 commutative axiom of addition Step c 3x + 0 = 3 additive inverse
9) The above diagram would be least appropriate for illustrating which of the following?
Step d 3x = 3 additive identity
A) 7 × 4 + 3 A) step a
B) 31 ÷ 8
B) step b
C) 28 × 3
C) step c D) 31 - 3 D) step d
10) 24 - 3 × 7 + 2 =
7) Which of the following sets is closed under division?
A) 5
A) integers
B) 149
B) rational numbers
C) –3
C) natural numbers
D) 189
D) whole numbers
MIDDLE LEVEL MATH.
115
TEACHER CERTIFICATION STUDY GUIDE 11)
Which of the following does not correctly relate an inverse operation?
14) Given that x, y, and z are prime numbers, which of the following is true?
A) a - b = a + -b A) x + y is always prime B) a × b = b ÷ a B) xyz is always prime C)
a2 = a
D) a ×
1 a
C) xy is sometimes prime
=1
D) x + y is sometimes prime
12) Mr. Brown feeds his cat premium cat food which costs $40 per month. Approximately how much will it cost to feed her for one year?
15) Find the GCF of 22 . 32 . 5 and 22 . 3 . 7. A) 25 . 33 . 5 . 7 B) 2 . 3 . 5 . 7
A) $500
C) 22 . 3
B) $400
D) 23 . 32 . 5 .7
C) $80 D) $4800
16) Given even numbers x and y, which could be the LCM of x
13) Given that n is a positive even integer, 5n + 4 will always be divisible by: A)
4
B)
5
C)
5n
D)
2
and y? A)
xy 2
B) 2xy C) 4xy D) xy
MIDDLE LEVEL MATH.
116
TEACHER CERTIFICATION STUDY GUIDE 17) (3.8 × 1017) × (.5 × 10-12 )
20) Solve for x:
A) 19 × 105 B) 1.9 ×10
4 8 = x 3
A) .66666...
5
B) .6
C) 1.9 ×10
6
D) 1.9 ×10
7
C) 15 D) 1.5 -3
18) 2 is equivalent to 21) Choose the set in which the members are not equivalent.
A) .8
19)
B) -.8
A) 1/2, 0.5 , 50%
C) 125
B) 10/5, 2.0 , 200%
D) 125
C) 3/8, 0.385, 38.5%
3.5 × 10-10 0.7 × 104
D) 7/10, 0.7 , 70%
A) 0.5 ×10
22) If three cups of concentrate are needed to make 2 gallons of fruit punch, how many cups are needed to make 5 gallons?
6
B) 5.0 ×10-6 C) 5.0 × 10-14 D) 0.5 ×10
A) 6 cups
-14
B) 7 cups C) 7.5 cups D) 10 cups
MIDDLE LEVEL MATH.
117
TEACHER CERTIFICATION STUDY GUIDE 26) Given a drawer with 5 black socks, 3 blue socks, and 2 red socks, what is the probability that you will draw two black socks in two draws in a dark room?
23) A sofa sells for $520. If the retailer makes a 30% profit, what was the wholesale price? A) $400 B) $676
A) 2/9
C) $490
B) 1/4
D) $364
C) 17/18 D) 1/18
24) Given a spinner with the numbers one through eight, what is the probability that you will spin an even number or a number greater than four?
27) A sack of candy has 3 peppermints, 2 butterscotch drops and 3 cinnamon drops. One candy is drawn and replaced, then another candy is drawn; what is the probability that both will be butterscotch?
A) 1/4
A) 1/2
B) 1/2
B) 1/28
C) ¾
C) 1/4
D) 1
D) 1/16
25) If a horse will probably win three races out of ten, what are the odds that he will win?
28) Find the median of the following set of data: 14 3 7 6 11 20
A) 3:10 B) 7:10
A) 9
C) 3:7
B) 8.5
D) 7:3
C) 7 D) 11
MIDDLE LEVEL MATH.
118
TEACHER CERTIFICATION STUDY GUIDE 31) A student scored in the 87th percentile on a standardized test. Which would be the best interpretation of his score?
29) Corporate salaries are listed for several employees. Which would be the best measure of central tendency? $24,000
$24,000
$26,000
$28,000
$30,000
$120,000
A) Only 13% of the students who took the test scored higher. B) This student should be getting mostly B's on his report card.
A) mean B.) median
C) This student performed below average on the test.
C) mode D) This is the equivalent of missing 13 questions on a 100 question exam.
D) no difference 30) Which statement is true about George's budget?
32) A man's waist measures 90 cm. What is the greatest possible error for the measurement?
A) George spends the greatest portion of his income on food.
A) ± 1 m
B) George spends twice as much on utilities as he does on his mortgage.
B) ±8 cm
C) George spends twice as much on utilities as he does on food.
D) ±5 mm
C) ±1 cm
33) The mass of a cookie is closest to
D) George spends the same amount on food and utilities as he does on mortgage.
A) 0.5 kg B) 0.5 grams
utilities
C) 15 grams
mortgage D) 1.5 grams food misc
MIDDLE LEVEL MATH.
119
TEACHER CERTIFICATION STUDY GUIDE 37) Find the area of the figure below. 12 in
34) 3 km is equivalent to A) 300 cm B) 300 m
3 in
7 in
C) 3000 cm 5 in
D) 3000 m
A) 56 in2
35) 4 square yards is equivalent to
B) 27 in2 A) 12 square feet C) 71 in2 B) 48 square feet D) 170 in2 C) 36 square feet 38) Find the area of the shaded region given square ABCD with side AB=10m and circle E.
D) 108 square feet 36) If a circle has an area of 25 cm2, what is its circumference to the nearest tenth of a centimeter?
A
B
E A) 78.5 cm B) 17.7 cm
C
C) 8.9 cm
A) 178.5 m2
D) 15.7 cm
B) 139.25 m2 C) 71 m2 D) 60.75 m2
MIDDLE LEVEL MATH.
120
D
TEACHER CERTIFICATION STUDY GUIDE 39) Given similar polygons with corresponding sides of lengths 9 and 15, find the perimeter of the smaller polygon if the perimeter of the larger polygon is 150 units.
41) If the radius of a right cylinder is doubled, how does its volume change? A) no change B) also is doubled
A) 54 C) four times the original B) 135 D) pi times the original C) 90 42) Determine the volume of a sphere to the nearest cm3 if the surface area is 113 cm2.
D) 126 40)
A) 113 cm3 5m 8m
B) 339 cm3
3m
C) 37.7 cm3
10 m 6m
D) 226 cm3 43) Compute the surface area of the prism.
12 m Compute the area of the polygon shown above.
5 A) 178 m
5
2
12
B) 154 m2
6
C) 43 m2
A) 204
D) 188 m2
B) 216 C) 360 D) 180
MIDDLE LEVEL MATH.
121
TEACHER CERTIFICATION STUDY GUIDE 46) Given XY ≅ YZ and ∠AYX ≅ ∠AYZ. Prove ∆AYZ ≅ ∆AYX.
44) If the base of a regular square pyramid is tripled, how does its volume change?
A A) double the original B) triple the original
X
Z Y
C) nine times the original 1) XY ≅YZ
D) no change
2) ∠AYX ≅∠AYZ 45) How does lateral area differ from total surface area in prisms, pyramids, and cones? A) For the lateral area, only use surfaces perpendicular to the base.
4) ∆AYZ ≅ ∆AYX Which property justifies step 3? A) reflexive
B) They are both the same.
B.) symmetric
C) The lateral area does not include the base.
B) transitive D) identity
D) The lateral area is always a factor of pi.
MIDDLE LEVEL MATH.
3) AY ≅ AY
122
TEACHER CERTIFICATION STUDY GUIDE 47) Given l1 l2 (parallel lines 1 & 2) prove ∠b ≅ ∠e
49) 7t - 4 •2t + 3t • 4 ÷ 2 = A) 5t
1) ∠b ≅ ∠d
1) vertical angle theorem B) 0
2) ∠d ≅ ∠e
2) alternate interior angle theorem
3) ∠b ≅ ∠3
3) symmetric axiom of equality
1
C) 31t D) 18t 50) Solve for x: 3x + 5 ≥ 8 + 7x
b d
2
A) x ≥ - 43 B) x ≤ - 43
e
Which step is incorrectly justified?
C) x ≥
A) step 1
D) x ≤
3 4
3 4
B) step 2 C) step 3
51) Solve for x: 2x +3 > 4
D) no error A) - 72 > x > 12 48) Simplify
x2y-3 2 3 xy 3 4
B) - 12 > x > C) x <
-4
A)
1 2
B)
1 2
x y
C)
9 8
-4
xy
D)
9 8
xy-2
xy
7 2
7 2
or x<- 12
D) x<- 72 or x> 12
-1 -4
52) 3x + 2y = 12 12x + 8y = 15 A) all real numbers B) x = 4, y = 4 C) x = 2, y = -1 D) ∅
MIDDLE LEVEL MATH.
123
TEACHER CERTIFICATION STUDY GUIDE 53) x = 3y + 7 7x + 5y = 23
55) Graph the solution: x + 7 < 13
A) (-1,4)
A) -6
0
6
-6
0
6
-6
0
6
-6
0
6
B) (4, -1) B) C) (
−29 7
,
−26 7
)
D) (10, 1)
C)
D)
56) Three less than four times a number is five times the sum of that number and 6. Which equation could be used to solve this problem? A) 3 - 4n = 5(n + 6) B) 3 - 4n + 5n = 6 54)
Which equation is represented by the above graph?
C) 4n - 3 = 5n + 6 D) 4n - 3 = 5(n + 6)
A) x – y = 3 57) A boat travels 30 miles upstream in three hours. It makes the return trip in one and a half hours. What is the speed of the boat in still water?
B) x – y = –3 C) x + y = 3 D) x + y = –3
A) 10 mph B) 15 mph C) 20 mph D) 30 mph
MIDDLE LEVEL MATH.
124
TEACHER CERTIFICATION STUDY GUIDE 58) Which set illustrates a function?
61) Which of the following is a factor of k3 - m3 ? A) k2+ m2
A) { (0,1) (0,2) (0,3) (0,4) }
B) k + m
B) { (3,9) (-3,9) (4,16) (-4,16)} C) { (1,2) (2,3) (3,4) (1,4) }
C) k2 - m2
D) { (2,4) (3,6) (4,8) (4,16) }
D) k - m 62) Solve for x.
59) Give the domain for the function over the set of real numbers:
3x2 - 2 + 4(x2 - 3) = 0
y = 3x + 2 2x – 3
A) {- 2 , B) {2, -2 }
A) all real numbers
3, - 3}
B) all real numbers, x ≠ 0
C) {0,
C) all real numbers, x ≠ -2 or 3
D) {7, -7 } 63) Solve:
± 6 D) all real numbers, x ≠ 2
75 + 147 – 48
A) 174
60) Factor completely: 8(x - y) + a(y - x)
B) 12 3
A) (8 + a) (y - x)
C) 8 3
B) (8 - a) (y - x)
D) 74
C) (a - 8) (y - x) D) (a - 8) (y + x)
MIDDLE LEVEL MATH.
2}
125
TEACHER CERTIFICATION STUDY GUIDE 64) The discriminant of a quadratic equation is evaluated and determined to be -3. The equation has
66) If y varies inversely as x and x is 4 when y is 6, what is the constant of variation? A) 2
A) one real root B) 12 B) one complex root C) 3/2 C) two roots, both real D) 24 D) two roots, both complex 67) If y varies directly as x and x is 2 when y is 6, what is x when y is 18? A) 3 B) 6 C) 26 D) 36
65) Which equation is graphed above? A) y = 4 (x + 3)2 B) y = 4 (x – 3)2 C) y = 3 (x – 4)2 D) y = 3 (x + 4)2
MIDDLE LEVEL MATH.
126
TEACHER CERTIFICATION STUDY GUIDE 71)
68) {1,4,7,10, . . .} What is the 40th term in this sequence?
3
A) 43
2
1
l1
5
l2 7
4 6
8
B) 121 Given l1 l 2 (parallel lines 1 & 2) which of the following is true?
C) 118 D) 120
A) ∠1 and ∠8 are congruent and alternate interior angles
69) {6,11,16,21, . .} Find the sum of the first 20 terms in the sequence.
B) ∠2 and ∠3 are congruent and corresponding angles C) ∠3 and ∠4 are adjacent and supplementary angles
A) 1070 B) 1176
D) ∠3 and ∠5 are adjacent and supplementary angles
C) 969 72 )
D) 1069 70) Two non-coplanar lines which do not intersect are labeled
1
A) parallel lines B) perpendicular lines Given the regular hexagon above, determine the measure of angle ∠1.
C) skew lines D) alternate exterior lines
A) 30o B) 60o C) 120o D) 45° MIDDLE LEVEL MATH.
127
TEACHER CERTIFICATION STUDY GUIDE 75)
73)
Q c a
T S
b
d
e
R Which of the following statements is true about the number of degrees in each angle? A) a + b + c = 180
U
Given QS ≅ TS and RS ≅US, prove ∆QRS ≅ ∆TUS. l) QS ≅ TS 2) RS ≅ US 3) ∠TSU ≅ ∠QSR 4) ∆TSU ≅ ∆QSR
o
B) a = e
1) Given 2) Given 3) ? 4) SAS
Give the reason which justifies step 3.
C) b + c = e D) c + d = e
A) Congruent parts of congruent triangles are congruent B) Reflexive axiom of equality
74)
C) Alternate interior angle Theorem D) Vertical angle theorem
What method could be used to prove the above triangles congruent? A) SSS B) SAS C) AAS D) SSA
MIDDLE LEVEL MATH.
128
TEACHER CERTIFICATION STUDY GUIDE 76) Given similar polygons with corresponding sides 6 and 8, what is the area of the smaller if the area of the larger is 64?
78) A
A) 48 7
L
B) 36
K
14
M
Given altitude AK with measurements as indicated, determine the length of AK. A) 98
C) 144 D) 78
B) 7 2
77) In similar polygons, if the perimeters are in a ratio of x:y, the sides are in a ratio of
C)
A) x:y
21
D) 7 3
B) x2:y2
79)
C) 2x:y
A
D) 1/2 x:y
30
B
C
If AC = 12, determine BC. A) 6 B) 4 C) 6 3 D) 3 6
MIDDLE LEVEL MATH.
129
TEACHER CERTIFICATION STUDY GUIDE 82)
80)
C
A L
50
A
What is the measure of major arc AL ?
B D
A) 50
o
B) 25
o
The above construction can be completed to make: A) an angle bisector
C) 100o B) parallel lines D) 310
o
C) a perpendicular bisector 81) D) skew lines K
83)
R
M A R
K B N
M
A line from R to K will form
If arc KR = 70° what is the measure of ∠M? A) 290 B) 35
A) an altitude of RMN
o
B) a perpendicular bisector of MN
o
C) 140°
C) a bisector of MRN
D) 110°
D) a vertical angle
MIDDLE LEVEL MATH.
130
TEACHER CERTIFICATION STUDY GUIDE 86)
84) Which is a postulate?
A
F
A) The sum of the angles in any triangle is 180o. B) A line intersects a plane in one point. B
C) Two intersecting lines from congruent vertical angles.
D
E
Which theorem could be used to prove ∆ABD ≅ ∆CEF, given BC ≅ DE, ∠C ≅ ∠D, and AD ≅ CF?
D) Any segment is congruent to itself.
A) ASA 85) Which of the following can be defined?
B) SAS
A) point
C) SAA
B) ray
D) SSS
C) line D) plane
MIDDLE LEVEL MATH.
C
131
TEACHER CERTIFICATION STUDY GUIDE 88) Find the distance between (3,7) and (-3,4).
87) X
A) 9 H
K B) 45 C) 3 5
Y
L
M
D) 5 3
Z
89) Find the midpoint of (2,5) and (7,-4).
Prove ∆HYM ≅ ∆KZL, given XZ ≅ XY, ∠L ≅ ∠M and YL ≅ MZ 1) XZ ≅ XY 2) ∠Y ≅ ∠Z 3) ∠L ≅ ∠M 4) YL ≅ MZ 5) LM ≅ LM 6) YM ≅ LZ 7) ∆HYM ≅ ∆KZL
A) (9,-1)
1) Given 2) ? 3) Given 4) Given 5) ? 6) Add 7) ASA
B) (5,9) C) (9/2 , -1/2) D) (9/2, 1/2) 90) Given segment AC with B as its midpoint find the coordinates of C if A = (5,7) and B = (3, 6.5).
Which could be used to justify steps 2 and 5? A) CPCTC, Identity
A) (4, 6.5)
B) Isosceles Triangle Theorem, Identity
B) (1, 6) C) (2, 0.5)
C) SAS, Reflexive D) (16, 1) D) Isosceles Triangle Theorem, Reflexive
MIDDLE LEVEL MATH.
132
TEACHER CERTIFICATION STUDY GUIDE 93) Identify the proper sequencing of subskills when teaching graphing inequalities in two dimensions
91)
The above diagram is most likely used in deriving a formula for which of the following? A) the area of a rectangle B) the area of a triangle
B) graphing points, graphing lines, determining whether a line is solid or broken, shading regions C) graphing points, shading regions, determining whether a line is solid or broken, graphing lines
C) the perimeter of a triangle D) the surface area of a prism
D) graphing lines, determining whether a line is solid or broken, graphing points, shading regions
92) A student turns in a paper with this type of error: 7 + 16 ÷ 8 × 2 = 8 8 - 3 × 3 + 4 = -5
94) Sandra has $34.00, Carl has $42.00. How much more does Carl have than Sandra?
In order to remediate this error, a teacher should: A) review and drill basic number facts
Which would be the best method for finding the answer?
B) emphasize the importance of using parentheses in simplifying expressions
A) addition B) subtraction
C) emphasize the importance of working from left to right when applying the order of operations
C) division D) both A and B are equally correct
D) do nothing; these answers are correct
MIDDLE LEVEL MATH.
A) shading regions, graphing lines, graphing points, determining whether a line is solid or broken
133
TEACHER CERTIFICATION STUDY GUIDE 97) According to Piaget, at which developmental level would a child be able to learn formal algebra?
95) Which is the least appropriate strategy to emphasize when teaching problem solving? A) guess and check
A) pre-operational
B) look for key words to indicate operations such as all together-add, more thansubtract, times-multiply
B) sensory-motor C) abstract D) concrete operational
C) make a diagram 98) Which statement is incorrect? D) solve a simpler version of the problem
A) Drill and practice is one good use for classroom computers.
96) Choose the least appropriate set of manipulatives for a six grade class.
B) Some computer programs can help to teach problem solving.
A) graphic calculators, compasses, rulers, conic section models
C) Computers are not effective unless each child in the class has his own workstation.
B) two color counters, origami paper, markers, yarn
D) Analyzing science project data on a computer during math class is an excellent use of class time.
C) balance, meter stick, colored pencils, beads D) paper cups, beans, tangrams, geoboards
MIDDLE LEVEL MATH.
134
TEACHER CERTIFICATION STUDY GUIDE 98) Given a,b,y, and z are real numbers and ay + b = z, Prove y = z + -b a Statement Reason 1) ay + b = z 1) Given 2) -b is a real number 2) Closure
101. Change .63 into a fraction in simplest form. A) B) C) D)
3) (ay +b) + -b = z + -b
3) Addition property of Identity 4) ay + (b + -b) = z + -b 4) Associative 5) ay + 0 = z + -b 5) Additive inverse 6) ay = z + -b 6) Addition property of identity 7) a = z + -b 7) Division y 99)
Which reason is incorrect for the corresponding statement?
A) step 3
C) step 5 D) step 6
I) {½, 1, 2, 4} II) {-1, 1} III) {-1, 0, 1} A) B) C) D)
I only II only III only I and II
103. Which of the following illustrates an inverse property? a+b=a-b a+b=b+a a+0=a a + (-a) =0
104. f ( x) = 3 x − 2; f −1 ( x) =
100) Seventh grade students are working on a project using non-standard measurement. Which would not be an appropriate instrument for measuring the length of the classroom?
A) B) C) D)
3x + 2 x/6 2x − 3 ( x + 2) / 3
105. What would be the total cost of a suit for $295.99 and a pair of shoes for $69.95 including 6.5% sales tax?
A) a student’s foot B) a student’s arm span
A) B) C) D)
C) a student’s jump D) all are appropriate MIDDLE LEVEL MATH.
102. Which of the following sets is closed under division?
A) B) C) D)
B) step 4
63 100 7 11 6 3 10 23
135
$389.73 $398.37 $237.86 $315.23
TEACHER CERTIFICATION STUDY GUIDE 106. A student had 60 days to appeal the results of an exam. If the results were received on March 23, what was the last day that the student could appeal? A) B) C) D)
May 21 May 22 May 23 May 24
110. Compute the area of the shaded region, given a radius of 5 meters. 0 is the center. A) B) C) D)
A 5
107. Which of the following is always composite if x is odd, y is even, and both x and y are greater than or equal to 2? A) B) C) D)
7.13 cm² 7.13 m² 78.5 m² 19.63 m²
B 0
x+ y 3x + 2 y 5xy 5x + 3 y
5
111. If the area of the base of a cone is tripled, the volume will be A) B) C) D)
108. Which of the following is incorrect? A) ( x 2 y 3 ) 2 = x 4 y 6 B) m 2 (2n)3 = 8m 2 n3 C) (m3n 4 ) /(m 2 n 2 ) = mn 2 D) ( x + y 2 ) 2 = x2 + y 4
the same as the original 9 times the original 3 times the original 3 π times the original
112. Find the area of the figure pictured below. 4m 3m
109. Express .0000456 in scientific notation. A) B) C) D)
10m
4.56 x10−4 45.6 x10−6 4.56 x10−6 4.56 x10−5
MIDDLE LEVEL MATH.
7m A) B) C) D)
136
136.47 m² 148.48 m² 293.86 m² 178.47 m²
TEACHER CERTIFICATION STUDY GUIDE 116. What conclusion can be drawn from the graph below?
113. The mass of a Chips Ahoy cookie would be approximately equal to: A) B) C) D)
35 30 25 20 15 10
1 kilogram 1 gram 15 grams 15 milligrams
114. Compute the median for the following data set:
K
Girls
14.5 15.17 15 16
A)
115. Half the students in a class scored 80% on an exam, most of the rest scored 85% except for one student who scored 10%. Which would be the best measure of central tendency for the test scores? A) B) C) D)
mean median mode either the median or the mode because they are equal
MIDDLE LEVEL MATH.
2
3
MLK Elementary Student Enrollment
{12, 19, 13, 16, 17, 14} A) B) C) D)
1
137
B) C) D)
Boys
The number of students in first grade exceeds the number in second grade. There are more boys than girls in the entire school. There are more girls than boys in the first grade. Third grade has the largest number of students.
TEACHER CERTIFICATION STUDY GUIDE 117) State the domain of the 3x − 6 function f ( x) = 2 x − 25 A) B) C) D)
121. Which graph represents the equation of = y x 2 + 3x ?
x≠2 x ≠ 5, −5 x ≠ 2, −2 x≠5
A)
B)
C)
D)
y
1 1
x
118. What is the equation of the above graph? A) B) C) D)
2x + y = 2 2x − y = −2 2x − y = 2 2x + y = −2
122. The volume of water flowing through a pipe varies directly with the square of the radius of the pipe. If the water flows at a rate of 80 liters per minute through a pipe with a radius of 4 cm, at what rate would water flow through a pipe with a radius of 3 cm?
119. Solve for v0 = : d at (vt − v0 ) A) = v0 B) v0= C) = v0 D) = v0
atd − vt d − atvt atvt − d ( atvt − d ) / at
A) B) C) D)
120. Which of the following is a factor of 6 + 48m3 A) B) C) D)
(1 + 2m) (1 - 8m) (1 + m - 2m) (1 - m + 2m)
MIDDLE LEVEL MATH.
138
45 liters per minute 6.67 liters per minute 60 liters per minute 4.5 liters per minute
TEACHER CERTIFICATION STUDY GUIDE 123) Solve the system of equations for x, y and z.
127. Evaluate 31 2 (91 3 ) A) B) C) D)
3x + 2 y − z = 0 2x + 5 y = 8z x + 3y + 2z = 7
A) B) C) D)
(−1, 2, 1) (1, 2, − 1) (−3, 4, − 1) (0, 1, 2)
128. Simplify: A) B) C) D)
124. Solve for x : 18= 4 + 2 x A) B) C) D)
{−11, 7} {−7 ,0, 7} {−7, 7} {−11, 11}
A) B) C) D)
2
B) -3
0
A) B) C) D)
C) -2
0
2
0
2 3
75
15 3 10 1 + 3i
−1.25(1 − 3i ) 1.25(1 + 3i ) 1 + 3i 1 − 3i
130. Find the sum of the first one hundred terms in the progression. (-6, -2, 2 . . . )
A) 0
27 +
8 3 34 34 3
129. Simplify:
125. Which graph represents the solution set for x 2 − 5 x > −6 ?
-2
275 6 97 12 35 6 36 7
19,200 19,400 -604 604
D) -3
131. How many ways are there to choose a potato and two green vegetables from a choice of three potatoes and seven green vegetables?
126. Find the zeroes of f ( x) = x3 + x 2 − 14 x − 24 A) B) C) D)
4, 3, 7, 4,
3, 2 -8 -2, -1 -3, -2
MIDDLE LEVEL MATH.
A) B) C) D) 139
126 63 21 252
TEACHER CERTIFICATION STUDY GUIDE 132. What would be the seventh term of the expanded binomial (2a + b)8 ? A) B) C) D)
137. What is the measure of minor arc AD, given measure of arc PS is 40° and m < K = 10 ? A) B) C) D)
2ab 7 41a 4b 4 112a 2b6 16ab7
133. Which term most accurately describes two coplanar lines without any common points? A) B) C) D)
perpendicular parallel intersecting skew
A)
15 16 17 18
B)
135. What is the degree measure of each interior angle of a regular 10 sided polygon? A) B) C) D)
C)
18° 36° 144° 54°
136. If a ship sails due south 6 miles, then due west 8 miles, how far is it from its starting point? A) B) C) D)
D)
100 miles 10 miles 14 miles 48 miles
MIDDLE LEVEL MATH.
D
P
K A S
138. Choose the diagram which illustrates the construction of a perpendicular to the line at a given point on the line.
134. Determine the number of subsets of set K. K = {4, 5, 6, 7} A) B) C) D)
50° 20° 30° 25°
140
TEACHER CERTIFICATION STUDY GUIDE 139. When you begin by assuming the conclusion of a theorem is false, then show that through a sequence of logically correct steps you contradict an accepted fact, this is known as A) B) C) D)
142. Choose the correct statement concerning the median and altitude in a triangle. A) The median and altitude of a triangle may be the same segment. B) The median and altitude of a triangle are always different segments. C) The median and altitude of a right triangle are always the same segment. D) The median and altitude of an isosceles triangle are always the same segment.
inductive reasoning direct proof indirect proof exhaustive proof
140. Which theorem can be used to prove ∆BAK ≅ ∆MKA ? B
M
A A) B) C) D)
143. Which mathematician is best known for his work in developing non-Euclidean geometry?
K
SSS ASA SAS AAS
A) B) C) D)
141. Given that QO⊥NP and QO=NP, quadrilateral NOPQ can most accurately be described as a P
Q A) B) C) D)
144. Find the surface area of a box which is 3 feet wide, 5 feet tall, and 4 feet deep.
O
A) B) C) D)
N
parallelogram rectangle square rhombus
MIDDLE LEVEL MATH.
Descartes Riemann Pascal Pythagoras
141
47 sq. ft. 60 sq. ft. 94 sq. ft 188 sq. ft.
TEACHER CERTIFICATION STUDY GUIDE 145. Given a 30 meter x 60 meter garden with a circular fountain with a 5 meter radius, calculate the area of the portion of the garden not occupied by the fountain. A) B) C) D)
146. Determine the area of the shaded region of the trapezoid in terms of x and y. B y
1721 m² 1879 m² 2585 m² 1015 m²
A
3x D E
A) 4xy B) 2xy C) 3x 2 y D) There is not enough information given.
MIDDLE LEVEL MATH.
142
3x
x
C
TEACHER CERTIFICATION STUDY GUIDE Answer Key 1. A 2. C 3. D 4. A 5. B 6. B 7. B 8. D 9. C 10. A 11. B 12. A 13. D 14. D 15. C 16. A 17. B 18. D 19. C 20. D 21. C 22. C 23. A 24. C 25. C 26. A 27. D 28. A 29. B 30. C 31. A 32. C 33. C 34. D 35. C 36. B 37. A
75. D 76. B 77. A 78. B 79. A 80. D 81 B 82. C 83. C 84. D 85. B 86. B 87. D 88. C 89. D 90. B 91. 2 92. C 93. B 94. D 95. B 96. A 97. C 98. C 99. A 100.D 101.B 102.B 103.D 104.D 105.A 106.B 107.C 108.D 109.D 110.B 111.C
38. D 39. C 40. B 41. C 42. A 43. B 44. B 45. C 46. A 47. C 48. C 49. A 50. B 51. D 52. D 53. B 54. C 55. A 56. D 57. B 58. B 59. D 60. C 61. D 62. A 63. C 64. D 65. B 66. D 67. B 68. C 69. A 70. C 71. C 72. A 73. C 74. C
MIDDLE LEVEL MATH.
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112.B 113.C 114.C 115.B 116.B 117.B 118.B 119.D 120.A 121.C 122.A 123.A 124.C 125.D 126.D 127.B 128.A 129.D 130.A 131.A 132.C 133.B 134.B 135.C 136.B 137.B 138.D 139.C 140.C 141.C 142.A 143.B 144.C 145.A 146.B
TEACHER CERTIFICATION STUDY GUIDE Rationales for Sample Questions The following statements represent one way to solve each problem and obtain a correct answer. 1) C The rational numbers are not a subset of the irrational numbers. All of the other statements are true. 2) C 5 is an irrational number. A and B can both be expressed as fractions. D can be simplified to -4, an integer and rational number. 3) D A complex number is the square root of a negative number. The complex number is defined as the square root of -1. A is rational, B and C are irrational. 4) A A proper subset is completely contained in, but not equal to, the original set. 5) B Illustrates the identity axiom of addition. A illustrates additive inverse, C illustrates the multiplicative inverse, and D illustrates the commutative axiom of addition. 6) B In simplifying from step a to step b, 3 replaced 7 - 4, therefore the correct justification would be subtraction or substitution. 7) B In order to be closed under division, when any two members of the set are divided the answer must be contained in the set. This is not true for integers, natural, or whole numbers as illustrated by the counter example 11/2 = 5.5. 8) D There are an infinite number of real numbers between any two real numbers. 9) C is inappropriate. A shows a 7x4 rectangle with 3 additional units. B is the division based on A . D shows how mental subtraction might be visualized leaving a composite difference.
MIDDLE LEVEL MATH.
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TEACHER CERTIFICATION STUDY GUIDE 10) A According to the order of operations, multiplication is performed first, then addition and subtraction from left to right. 11) B is always false. A, C, and D illustrate various properties of inverse relations. 12) A 12(40) = 480 which is closest to $500. 13) D 5n is always even. An even number added to an even number is always an even number, thus divisible by 2. 14) D x + y is sometimes prime. B and C show the products of two numbers which are always composite. x + y may be true, but not always, 15) C Choose the number of each prime factor that is in common. 16) A Although choices B, C and D are common multiples, when both numbers are even, the product can be divided by two to obtain the least common multiple. 17) B Multiply the decimals and add the exponents. 18) D Express as the fraction 1/8, then convert to a decimal. 19) C Divide the decimals and subtract the exponents. 20) D Cross multiply to obtain 12 = 8x, then divide both sides by 8. 21) C 3/8 is equivalent to .375 and 37.5% 22) C Set up the proportion 3/2 = x/5, cross multiply to obtain 15=2x, then divide both sides by 2. 23) A Let x be the wholesale price, then x + .30x = 520, 1.30x = 520. Divide both sides by 1.30. 24) C There are 8 favorable outcomes: 2,4,5,6,7,8 and 8 possibilities. Reduce 6/8 to 3/4. 25) C The odds are that he will win 3 and lose 7. 26) A In this example of conditional probability, the probability of drawing a black sock on the first draw is 5/10. It is implied in the problem that there is no replacement, therefore the probability of obtaining a black sock in the second draw is 4/9. Multiply the two probabilities and reduce to lowest terms.
MIDDLE LEVEL MATH.
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TEACHER CERTIFICATION STUDY GUIDE 27) D With replacement, the probability of obtaining a butterscotch on the first draw is 2/8 and the probability of drawing a butterscotch on the second draw is also 2/8. Multiply and reduce to lowest terms. 28) A Place the numbers in ascending order: 3 6 7 11 14 20. Find the average of the middle two numbers (7+11)12 =9 29) B The median provides the best measure of central tendency in this case, where the mode is the lowest number and the mean would be disproportionately skewed by the outlier $120,000. 30) C George spends twice as much on utilities as on food. 31) A Percentile ranking tells how the student compared to the norm or the other students taking the test. It does not correspond to the percentage answered correctly, but can indicate how the student compared to the average student tested. 32) D The greatest possible error of measurement is ± + 1/2 unit, in this case .5 cm or 5 mm. 33) C A cookie is measured in grams. 34) D To change kilometers to meters, move the decimal 3 places to the right. 35) C There are 9 square feet in a square yard. 36) B Find the radius by solving Πr2 = 25. Then substitute r=2.82 into C = 2Πr to obtain the circumference. 37) A Divide the figure into two rectangles with a horizontal line. The area of the top rectangle is 36 in, and the bottom is 20 in. 38) D Find the area of the square 102 = 100, then subtract 1/2 the area of the circle. The area of the circle is Πr2 = (3.14)(5)(5)=78.5. Therefore the area of the shaded region is 100 - 39.25 - 60.75. 39) C The perimeters of similar polygons are directly proportional to the lengths of their sides, therefore 9/15 = x/150. Cross multiply to obtain 1350 = 15x, then divide by 15 to obtain the perimeter of the smaller polygon. 40) B Divide the figure into a triangle, a rectangle and a trapezoid. The area of the triangle is 1/2 bh = 1/2 (4)(5) = 10. The area of the rectangle is bh = 12(10) = 120. The area of the trapezoid is 1/2(b + B)h = 1/2(6 + 10)(3) = 1/2 (16)(3) = S4. Thus, the area of the figure is 10 + 120 + 24 =154.
MIDDLE LEVEL MATH.
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TEACHER CERTIFICATION STUDY GUIDE 41) C If the radius of a right circular cylinder is doubled, the volume is multiplied by four; because in the formula, the radius is squared. Therefore the new volume is 2 x 2 or four times the original. 42) A Solve for the radius of the sphere using A = 4Πr2. The radius is 3. Then, find the volume using 4/3 Πr3. Only when the radius is 3 are the volume and surface area equivalent. 43) B There are five surfaces which make up the prism. The bottom rectangle has an area 6 x 12 = 72. The sloping sides are two rectangles each with an area of 5 x 12 = 60. The height of the end triangles is determined to be 4 using the Pythagorean theorem. Therefore each triangle has area 1/2bh = 1/2(6)(4) -12. Thus, the surface area is 72 + 60 + 60 + 12 + 12 = 216. 44) B Using the general formula for a pyramid V = 1/3 bh, since the base is tripled and is not squared or cubed in the formula, the volume is also tripled. 45) C The lateral area does not include the base. 46) A The reflexive property states that every number or variable is equal to itself and every segment is congruent to itself. 47) C Step 3 can be justified by the transitive property. 48) C Simplify the complex fraction by inverting the denominator and multiplying: 3/4(3/2)=9/8, then subtract exponents to obtain the correct answer. 49) A First perform multiplication and division from left to right; 7t -8t + 6t, then add and subtract from left to right. 50) B Using additive equality, -3 ≥ 4x. Divide both sides by 4 to obtain -3/4 ≥ x. Carefully determine which answer choice is equivalent. 51) D The quantity within the absolute value symbols must be either > 4 or < -4. Solve the two inequalities 2x + 3 > 4 or 2x + 3 < -4 52) D Multiplying the top equation by -4 and adding results in the equation 0 = 33. Since this is a false statement, the correct choice is the null set. 53) B Substituting x in the second equation results in 7(3y + 7) + 5y = 23. Solve by distributing and grouping like terms: 26y+49 = 23, 26y = -26, y = -1 Substitute y into the first equation to obtain x.
MIDDLE LEVEL MATH.
147
TEACHER CERTIFICATION STUDY GUIDE 54) C By looking at the graph, we can determine the slope to be -1 and the y-intercept to be 3. Write the slope intercept form of the line as y = -1x + 3. Add x to both sides to obtain x + y = 3, the equation in standard form. 55) A Solve by adding -7 to each side of the inequality. Since the absolute value of x is less than 6, x must be between -6 and 6. The end points are not included so the circles on the graph are hollow. 56) D Be sure to enclose the sum of the number and 6 in parentheses. 57) B Let x = the speed of the boat in still water and c = the speed of the current.
upstream downstream
rate x-c x+c
time 3 1.5
distance 30 30
Solve the system: 3x - 3c = 30 1 .5x + 1 .5c = 30 58) B Each number in the domain can only be matched with one number in the range. A is not a function because 0 is mapped to 4 different numbers in the range. In C, 1 is mapped to two different numbers. In D, 4 is also mapped to two different numbers. 59) D Solve the denominator for 0. These values will be excluded from the domain. 2x2 - 3 = 0 2x2 = 3 x2 = 3/2 x = 23 = 23 • 22 = ± 2 6 60) C Glancing first at the solution choices, factor (y - x) from each term. This leaves -8 from the first term and a from the seconnd term: (a - 8)(y - x) 61) D The complete factorization for a difference of cubes is (k - m)(k2 + mk + m2). 62) A Distribute and combine like terms to obtain 7x2 - 14 = 0. Add 14 to both sides, then divide by 7. Since x2 = 2, x = 2 63) C Simplify each radical by factoring out the perfect squares: 5 3 +7 3 -4 3 =8 3
MIDDLE LEVEL MATH.
148
TEACHER CERTIFICATION STUDY GUIDE 64) D The discriminate is the number under the radical sign. Since it is negative the two roots of the equation are complex. 65) B Since the vertex of the parabola is three units to the left, we choose the solution where 3 is subtracted from x, then the quantity is squared. 66) D The constant of variation for an inverse proportion is xy. 67) B y/x-216=x/18, Solve 36=6x. 68) C 69) A 70) C 71) C The angles in A are exterior. In B, the angles are vertical. The angles in D are consecutive, not adjacent. 72) A Each interior angle of the hexagon measures 120o. The isosceles triangle on the left has angles which measure 120, 30, and 30. By alternate interior angle theorem, ∠1 is also 30. 73) C In any triangle, an exterior angle is equal to the sum of the remote interior angles. 74) B Use SAS with the last side being the vertical line common to both triangles. 75) D Angles formed by intersecting lines are called vertical angles and are congruent. 76) B In similar polygons, the areas are proportional to the squares of the sides. 36/64 = x/64 62:82 ; 36:64 77) A The sides are in the same ratio. 78) B The altitude from the right angle to the hypotenuse of any right triangle is the geometric mean of the two segments which are formed. Multiply 7 x 14 and take the square root. 79) A In a 30-60- 90 right triangle, the leg opposite the 30o angle is half the length of the hypotenuse. 80) D Minor arc AC measures 50o, the same as the central angle. To determine the measure of the major arc, subtract from 360.
MIDDLE LEVEL MATH.
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TEACHER CERTIFICATION STUDY GUIDE 81) C An inscribed angle is equal to one half the measure of the intercepted arc. 82) C The points marked C and D are the intersection of the circles with centers A and B. 83) C Using a compass, point K is found to be equidistant from A and B. 84) D A postulate is an accepted property of real numbers or geometric figures which cannot be proven, A, B. and C are theorems which can be proven. 85) B The point, line, and plane are the three undefined concepts on which plane geometry is based. 86) B To obtain the final side, add CD to both BC and ED. 87) D The isosceles triangle theorem states that the base angles are congruent, and the reflexive property states that every segment is congruent to itself. 88) C Using the distance formula
[3 − ( −3)]2 =
+ (7 - 4)2
36 + 9
=
3 5 89) D Using the midpoint formula x = (2 + 7)/2
y = (5 + -4)/2
90) B 91) B 92) C 93) B 94) D 95) B 96) A 97) C 98) C 99) A
MIDDLE LEVEL MATH.
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TEACHER CERTIFICATION STUDY GUIDE 100) D 101) Let N = .636363…. Then multiplying both sides of the equation by 100 or 10² (because there are 2 repeated numbers), we get 100N = 63.636363… 63 7 Then subtracting the two equations gives 99N = 63 or N = = . 99 11 Answer is B 4 = 8 and 8 is not in the set. .5 1 III is not closed because is undefined. 0 −1 1 1 −1 II is closed because = −1, = −1, = 1, = 1 and all the answers are in 1 −1 1 −1 the set. Answer is B
102) I is not closed because
103) Answer is D because a + (-a) = 0 is a statement of the Additive Inverse Property of Algebra. 104) To find the inverse, f-1(x), of the given function, reverse the variables in the given equation, y = 3x – 2, to get x = 3y – 2. Then solve for y as follows: x+2 x+2 = 3y, and y = . Answer is D. 3 105) Before the tax, the total comes to $365.94. Then .065(365.94) = 23.79. With the tax added on, the total bill is 365.94 + 23.79 = $389.73. (Quicker way: 1.065(365.94) = 389.73.) Answer is A 106) Recall: 30 days in April and 31 in March. 8 days in March + 30 days in April + 22 days in May brings him to a total of 60 days on May 22. Answer is B. 107) A composite number is a number which is not prime. The prime number sequence begins 2,3,5,7,11,13,17,…. To determine which of the expressions is always composite, experiment with different values of x and y, such as x=3 and y=2, or x=5 and y=2. It turns out that 5xy will always be an even number, and therefore, composite, if y=2. Answer is C. 108) Using FOIL to do the expansion, we get (x + y2)2 = (x + y2)(x + y2) = x2 + 2xy2 + y4. Answer is D. 109) In scientific notation, the decimal point belongs to the right of the 4, the first significant digit. To get from 4.56 x 10-5 back to 0.0000456, we would move the decimal point 5 places to the left. Answer is D.
MIDDLE LEVEL MATH.
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TEACHER CERTIFICATION STUDY GUIDE 90 = .25 110) Area of triangle AOB is .5(5)(5) = 12.5 square meters. Since 360 , the area of sector AOB (pie-shaped piece) is approximately .25( π )52 = 19.63. Subtracting the triangle area from the sector area to get the area of segment AB, we get approximately 19.63-12.5 = 7.13 square meters. Answer is B. 1 Bh , (font)where B is the area 3 of the circular base and h is the height. If the area of the base is tripled, the 1 volume becomes V = (3B)h = Bh (font), or three times the original area. 3 Answer is C.
111) The formula for the volume of a cone is V =
112) Divide the figure into 2 rectangles and one quarter circle. The tall rectangle on the left will have dimensions 10 by 4 and area 40. The rectangle in the center will have dimensions 7 by 10 and area 70. The quarter circle will have area .25( π )72 = 38.48. The total area is therefore approximately 148.48. Answer is B. 113) Since an ordinary cookie would not weigh as much as 1 kilogram, or as little as 1 gram or 15 milligrams, the only reasonable answer is 15 grams. Answer is C. 114) Arrange the data in ascending order: 12,13,14,16,17,19. The median is the middle value in a list with an odd number of entries. When there are an even number of entries, the median is the mean of the two center entries. Here the average of 14 and 16 is 15. Answer is C. 115) In this set of data, the median (see #14) would be the most representative measure of central tendency, since the median is independent of extreme values. Because of the 10% outlier, the mean (average) would be disproportionately skewed. In this data set, it is true that the median and the mode (number which occurs most often) are the same, but the median remains the best choice because of its special properties. Answer is B. 116) In kindergarten, first grade, and third grade, there are more boys than girls. The number of extra girls in grade two is more than made up for by the extra boys in all the other grades put together. Answer is B. 117) The values of 5 and –5 must be omitted from the domain of all real numbers because if x took on either of those values, the denominator of the fraction would have a value of 0, and therefore the fraction would be undefined. Answer is B.
MIDDLE LEVEL MATH.
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TEACHER CERTIFICATION STUDY GUIDE 118) By observation, we see that the graph has a y-intercept of 2 and a slope of 2/1 = 2. Therefore its equation is y = mx + b = 2x + 2. Rearranging the terms gives 2x – y = -2. Answer is B. 119) Using the Distributive Property and other properties of equality to isolate v0 atvt − d gives d = atvt – atv0, atv0 = atvt – d, v0 = . Answer is D.
at
120) Removing the common factor of 6 and then factoring the sum of two cubes gives 6 + 48m3 = 6(1 + 8m3) = 6(1 + 2m)(12 – 2m + (2m)2). Answer is A. 121) B is not the graph of a function. D is the graph of a parabola where the coefficient of x2 is negative. A appears to be the graph of y = x2. To find the x-intercepts of y = x2 + 3x, set y = 0 and solve for x: 0 = x2 + 3x = x(x + 3) to get x = 0 or x = -3. Therefore, the graph of the function intersects the x-axis at x=0 and x=-3. Answer is C.
V V 80 V = . Solving 2 = 2 . Substituting gives r r 16 9 for V gives 45 liters per minute. Answer is A.
122) Set up the direct variation:
123) Multiplying equation 1 by 2, and equation 2 by –3, and then adding together the two resulting equations gives -11y + 22z = 0. Solving for y gives y = 2z. In the meantime, multiplying equation 3 by –2 and adding it to equation 2 gives –y – 12z = -14. Then substituting 2z for y, yields the result z = 1. Subsequently, one can easily find that y = 2, and x = -1. Answer is A. 124) Using the definition of absolute value, two equations are possible: 18 = 4 + 2x or 18 = 4 – 2x. Solving for x gives x = 7 or x = -7. Answer is C. 125) Rewriting the inequality gives x2 – 5x + 6 > 0. Factoring gives (x – 2)(x – 3) > 0. The two cut-off points on the number line are now at x = 2 and x = 3. Choosing a random number in each of the three parts of the number line, we test them to see if they produce a true statement. If x = 0 or x = 4, (x-2) (x-3)>0 is true. If x = 2.5, (x-2)(x-3)>0 is false. Therefore the solution set is all numbers smaller than 2 or greater than 3. Answer is D. 126) Possible rational roots of the equation 0 = x3 + x2 – 14x -24 are all the positive and negative factors of 24. By substituting into the equation, we find that –2 is a root, and therefore that x+2 is a factor. By performing the long division (x3 + x2 – 14x – 24)/(x+2), we can find that another factor of the original equation is x2 – x – 12 or (x-4)(x+3). Therefore the zeros of the original function are –2, -3, and 4. Answer is D. 1 2 2 3
7 6
127) Getting the bases the same gives us 3 3 . Adding exponents gives 3 . Then some additional manipulation of exponents produces 7 6
3 =3
14 12
= (3
7 2 12
)
7 12
= 9 . Answer is B.
MIDDLE LEVEL MATH.
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TEACHER CERTIFICATION STUDY GUIDE 128) Simplifying radicals gives
27 + 75 = 3 3 + 5 3 = 8 3 . Answer is A.
129) Multiplying numerator and denominator by the conjugate gives 1 − 3i 10(1− 3i ) 10(1 − 3i) 10(1 − 3i ) 10 × = = = = 1 − 3i . Answer is D. 2 1 + 3i 1 − 3i 1 − 9i 1 − 9(−1) 10 130) To find the 100th term: t100 = -6 + 99(4) = 390. To find the sum of the first 100 100 terms: S = (−6 + 390) = 19200 . Answer is A. 2 131) There are 3 slots to fill. There are 3 choices for the first, 7 for the second, and 6 for the third. Therefore, the total number of choices is 3(7)(6) = 126. Answer is A. 132) The set-up for finding the seventh term is
8(7)(6)(5)(4)(3) (2a )8 −6 b6 which 6(5)(4)(3)(2)(1)
gives 28(4a2b6) or 112a2b6. Answer is C. 133) By definition, parallel lines are coplanar lines without any common points. Answer is B. 134) A set of n objects has 2n subsets. Therefore, here we have 24 = 16 subsets. These subsets include four which have only 1 element each, six which have 2 elements each, four which have 3 elements each, plus the original set, and the empty set. Answer is B. 135) Formula for finding the measure of each interior angle of a regular polygon (n − 2)180 8(180) with n sides is . For n=10, we get = 144 . Answer is C. 10 n 136) Draw a right triangle with legs of 6 and 8. Find the hypotenuse using the Pythagorean Theorem. 62 + 82 = c2. Therefore, c = 10 miles. Answer is B. 137) The formula relating the measure of angle K and the two arcs it intercepts is 1 m∠K = (mPS − mAD). Substituting the known values, we get 2 1 10 = (40 − mAD) . Solving for mAD gives an answer of 20 degrees. 2 Answer is B. 138) Given a point on a line, place the compass point there and draw two arcs intersecting the line in two points, one on either side of the given point. Then using any radius larger than half the new segment produced, and with the pointer at each end of the new segment, draw arcs which intersect above the line. Connect this new point with the given point. Answer is D.
MIDDLE LEVEL MATH.
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TEACHER CERTIFICATION STUDY GUIDE 139) By definition this describes the procedure of an indirect proof. Answer is C. 140) Since side AK is common to both triangles, the triangles can be proved congruent by using the Side-Angle-Side Postulate. Answer is C. 141) In an ordinary parallelogram, the diagonals are not perpendicular or equal in length. In a rectangle, the diagonals are not necessarily perpendicular. In a rhombus, the diagonals are not equal in length. In a square, the diagonals are both perpendicular and congruent. Answer is C. 142) The most one can say with certainty is that the median (segment drawn to the midpoint of the opposite side) and the altitude (segment drawn perpendicular to the opposite side) of a triangle may coincide, but they more often do not. In an isosceles triangle, the median and the altitude to the base are the same segment. Answer is A. 143) In the mid-nineteenth century, Reimann and other mathematicians developed elliptic geometry. Answer is B. 144) Let’s assume the base of the rectangular solid (box) is 3 by 4, and the height is 5. Then the surface area of the top and bottom together is 2(12) = 24. The sum of the areas of the front and back are 2(15) = 30, while the sum of the areas of the sides are 2(20)=40. The total surface area is therefore 94 square feet. Answer is C. 145) Find the area of the garden and then subtract the area of the fountain: 30(60)- π (5)2 or approximately 1721 square meters. Answer is A. 146) To find the area of the shaded region, find the area of triangle ABC and then subtract the area of triangle DBE. The area of triangle ABC is .5(6x)(y) = 3xy. The area of triangle DBE is .5(2x)(y) = xy. The difference is 2xy. Answer is B.
MIDDLE LEVEL MATH.
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